U.S. patent number 8,674,527 [Application Number 13/111,717] was granted by the patent office on 2014-03-18 for apparatuses and methods for energy storage.
This patent grant is currently assigned to Energy Cache, Inc.. The grantee listed for this patent is James T. Baker, Aaron D. Fyke, Christian T. Gregory, William T. Gross, Braden E. Hines. Invention is credited to James T. Baker, Aaron D. Fyke, Christian T. Gregory, William T. Gross, Braden E. Hines.
United States Patent |
8,674,527 |
Fyke , et al. |
March 18, 2014 |
**Please see images for:
( Certificate of Correction ) ** |
Apparatuses and methods for energy storage
Abstract
Some embodiments relate to an energy storage and generation
system, comprising a cable system having a first end portion
located at a first elevation and a second end portion located at a
second elevation, a plurality of mass carriers supported by the
cable system, one or more motor generators coupled with the cable
system and with an energy grid, a control system in communication
with at least the one or more motor generators, a first mass pile
area configured to store mass medium positioned at the first
elevation, and a second mass pile area configured to store mass
medium positioned at the second elevation that can be higher than
the first elevation. The one or more motor generators can move the
cable system in an energy storing state and be moved by the cable
in an energy generating state. The system can store energy by
transferring mass medium from the first mass pile area to the
second mass pile area, and can generate energy by transferring mass
medium from the second mass pile area to the first mass pile
area.
Inventors: |
Fyke; Aaron D. (Altadena,
CA), Baker; James T. (Temple City, CA), Hines; Braden
E. (Pasadena, CA), Gross; William T. (Pasadena, CA),
Gregory; Christian T. (La Crescenta, CA) |
Applicant: |
Name |
City |
State |
Country |
Type |
Fyke; Aaron D.
Baker; James T.
Hines; Braden E.
Gross; William T.
Gregory; Christian T. |
Altadena
Temple City
Pasadena
Pasadena
La Crescenta |
CA
CA
CA
CA
CA |
US
US
US
US
US |
|
|
Assignee: |
Energy Cache, Inc. (Pasadena,
CA)
|
Family
ID: |
44971892 |
Appl.
No.: |
13/111,717 |
Filed: |
May 19, 2011 |
Prior Publication Data
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Document
Identifier |
Publication Date |
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US 20110285147 A1 |
Nov 24, 2011 |
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Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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61395994 |
May 20, 2010 |
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61458754 |
Dec 1, 2010 |
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Current U.S.
Class: |
290/1R;
290/7 |
Current CPC
Class: |
H02J
15/00 (20130101); H02K 7/1807 (20130101); H02J
3/28 (20130101) |
Current International
Class: |
F02B
63/04 (20060101); F03G 7/08 (20060101) |
Field of
Search: |
;290/1R ;60/675 |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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06-193553 |
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Jul 1994 |
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JP |
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10-0570880 |
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Apr 2006 |
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KR |
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10-2009-0110891 |
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Oct 2009 |
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KR |
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Other References
Wood, Bruce; "Hanging Tomato Plants"; Mar. 4, 2009; retrieved May
9, 2013 using Internet Archive to view rubberingot.com. cited by
examiner .
"A Weighting game," International Water Power & Dam
Construction, Apr. 13, 2010, 8 pages. cited by applicant .
Search Report/Written Opinion mailed Feb. 19, 2012, International
Application No. PCT/US2011/037252, 9 pages. cited by
applicant.
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Primary Examiner: Patel; Tulsidas C
Assistant Examiner: Quigley; Thomas
Attorney, Agent or Firm: Knobbe Martens Olson & Bear
LLP
Parent Case Text
PRIORITY INFORMATION AND INCORPORATION BY REFERENCE
This application claims priority benefit of U.S. Provisional
Application 61/395,994 (titled "ENERGY STORAGE SYSTEM"), filed May
20, 2010, and U.S. Provisional Application 61/458,754 (titled
"ENERGY STORAGE SYSTEM AND METHOD"), filed Dec. 1, 2010, which
applications are hereby incorporated by reference in their
entireties as if fully set forth herein. The benefit of priority is
claimed under the appropriate legal basis including, without
limitation, under 35 U.S.C. .sctn.119(e).
Claims
What is claimed is:
1. An energy storage and generation system, comprising: a cable
system comprising a cable, the cable system having a first end
portion located at a first elevation and a second end portion
located at a second elevation; a plurality of mass carriers
supported by the cable so that two or more of the mass carriers are
in motion when the cable is being driven; one or more motor
generators coupled with the cable system and with an electrical
grid, the one or more motor generators configured to drive the
cable system to store energy and configured to be driven by the
cable system to generate electricity for the electrical grid; a
control system in communication with at least the one or more motor
generators; a first mass pile area at the first elevation; a second
mass pile area at the second elevation; and a processor configured
for receiving a signal from a grid operator, and, based at least in
part on said signal, determining whether to store energy or
generate electricity for the electrical grid; wherein: the second
elevation is higher than the first elevation; the system is
configured to store energy by transferring mass medium from the
first mass pile area to the second mass pile area; the system is
configured to generate electricity by transferring mass medium from
the second mass pile area to the first mass pile area; the energy
storage and generation system is configured to: transfer mass
medium from the first mass pile area to at least one of the
plurality of mass carriers supported by the cable while at the same
time transferring mass medium from at least one of the plurality of
mass carriers supported by the same cable to the second mass pile
area at the second elevation; and transfer mass medium from the
second mass pile area to at least one of the plurality of mass
carriers supported by the cable while at the same time transferring
mass medium from at least one of the plurality of mass carriers
supported by the same cable to the first mass pile area at the
first elevation.
2. The energy storage system of claim 1, comprising one or more
discharge devices positioned beneath a portion of each of the first
mass pile area and the second first mass pile area.
3. The energy storage system of claim 2, wherein each discharge
device comprises a valve configured to move between an open
position and a closed position such that, when in an open position,
mass medium can be discharged from the respective mass pile area
and, when in a closed position, mass medium is substantially
prevented from being discharged from the respective mass pile
area.
4. The energy storage system of claim 3, wherein the system is
configured to load mass medium into the carriers by causing the
carriers to traverse underneath at least one discharge device.
5. The energy storage system of claim 1, comprising one or more
power electronics modules configured to condition the electricity
produced by the one or more motor generators for the electrical
grid.
6. The energy storage system of claim 1, wherein the plurality of
mass carriers are carriers positioned substantially uniformly along
substantially the entire length of the cable system.
7. The energy storage system of claim 1, further comprising a
tipping mechanism configured to selectively tip a given carrier so
as to cause the given carrier to discharge mass medium carried
thereby.
8. The energy storage system of claim 1, wherein the system is
configured to provide at least one of bulk energy storage, bulk
energy generation, frequency regulation, a combination of bulk
energy storage and frequency regulation, and a combination of bulk
energy generation and frequency regulation.
9. The energy storage system of claim 1, wherein the system is
configured to enhance energy frequency regulation, and at least:
bulk energy storage, or bulk energy generation, or both bulk energy
storage and bulk energy generation.
10. An energy storage and generation system, comprising: a cable
system comprising a cable, the cable system having a first portion
located at a first elevation and a second end portion located at a
second elevation; a plurality of mass carriers supported by the
cable so that two or more of the mass carriers are in motion when
the cable is being driven; one or more motor generators coupled
with the cable system and with an electrical grid, the one or more
motor generators configured to drive the cable system to store
energy and configured to be driven by the cable to generate
electricity for the electrical grid; a control system in
communication with at least the one or more motor generators; a
first mass pile area at the first elevation; a second mass pile
area at the second elevation; a processor configured for receiving
a signal from a grid operator, and, based at least in part on said
signal, determining whether to store energy or generate electricity
for the electrical grid; and one or more discharge devices
positioned beneath a portion of each of the first mass pile area
and the second first mass pile area; wherein: the second elevation
is higher than the first elevation; the system is configured to
store energy by transferring mass medium from the first mass pile
area to the second mass pile area; the system is configured to
generate electricity by transferring mass medium from the second
mass pile area to the first mass pile area; each discharge device
comprises a valve configured to move between an open position and a
closed position such that, when in an open position, mass medium
can be discharged from the respective mass pile area and, when in a
closed position, mass medium is substantially prevented from being
discharged from the respective mass pile area; and the energy
storage and generation system is configured to: transfer mass
medium from the first mass pile area to at least one of the
plurality of mass carriers supported by the cable while at the same
time transferring mass medium from at least one of the plurality of
mass carriers supported by the same cable to the second mass pile
area at the second elevation; and transfer mass medium from the
second mass pile area to at least one of the plurality of mass
carriers supported by the cable while at the same time transferring
mass medium from at least one of the plurality of mass carriers
supported by the same cable to the first mass pile area at the
first elevation.
11. The energy storage system of claim 10, wherein the first mass
pile comprises at least one of dirt, sand, rock, mine tailings,
gravel, or other similar native or naturally occurring
material.
12. The energy storage system of claim 10, wherein the system is
configured to provide at least one of bulk energy storage, bulk
energy generation, frequency regulation, a combination of bulk
energy storage and frequency regulation, and a combination of bulk
energy generation and frequency regulation.
13. An energy storage and generation system, comprising: a cable
system comprising a cable, the cable system having a first end
portion located at a first elevation and a second portion located
at a second elevation; a plurality of mass carriers supported by
the cable so that two or more of the mass carriers are in motion
when the cable is being driven; one or more motor generators
coupled with the cable system and with an electrical grid, the one
or more motor generators configured to drive the cable system to
store energy and configured to be driven by the cable to generate
electricity for the electrical grid; a control system in
communication with at least the one or more motor generators; a
first mass pile area at the first elevation; a second mass pile
area at the second elevation; and a processor configured for
receiving a signal from a grid operator, and, based at least in
part on said signal, determining whether to store energy or
generate electricity for the electrical grid; wherein: the second
elevation is higher than the first elevation; the system is
configured to store energy by transferring mass medium from the
first mass pile area to the second mass pile area; the system is
configured to generate electricity by transferring mass medium from
the second mass pile area to the first mass pile area; and the
plurality of mass carriers are positioned substantially uniformly
along substantially the entire length of the cable system; and the
cable system forms a continuous loop between the first portion and
the second portion such that the cable system can move one or more
mass carriers from the first elevation toward the second elevation
while simultaneously moving one or more mass carriers from the
second elevation toward the first elevation.
14. The energy storage system of claim 13, wherein at least a
portion of the carriers are configured to discharge the mass medium
carried thereby onto at least one of the first mass pile area and
the second mass pile area.
15. The energy storage system of claim 13, wherein the first mass
pile comprises at least one of dirt, sand, rock, mine tailings,
gravel, or other similar native or naturally occurring
material.
16. The energy storage system of claim 13, wherein the system is
configured to provide at least one of bulk energy storage, bulk
energy generation, frequency regulation, a combination of bulk
energy storage and frequency regulation, and a combination of bulk
energy generation and frequency regulation.
17. An energy storage and generation system, comprising: a cable
system comprising a cable, the cable system having a first portion
located at a first elevation and a second portion located at a
second elevation; a plurality of mass carriers supported by the
cable so that two or more of the mass carriers are in motion when
the cable is being driven; one or more motor generators coupled
with the cable system and with an electrical grid, the one or more
motor generators configured to drive the cable system to store
energy and configured to be driven by the cable to generate
electricity for the electrical grid; a control system in
communication with at least the one or more motor generators; a
first mass pile area at the first elevation; a second mass pile
area at the second elevation; a processor configured for receiving
a signal from a grid operator, and, based at least in part on said
signal, determining whether to store energy or generate electricity
for the electrical grid; and a tipping mechanism configured to
selectively tip a given carrier so as to cause the given carrier to
discharge mass medium carried thereby; wherein: the second
elevation is higher than the first elevation; the system is
configured to store energy by transferring the mass medium from the
first mass pile area to the second mass pile area; and the system
is configured to generate electricity by transferring mass medium
from the second mass pile area to the first mass pile area; and the
cable forms a continuous loop between the first portion and the
second portion such that the cable can move one or more mass
carriers from the first elevation toward the second elevation while
at the same time moving one or more mass carriers from the second
elevation toward the first elevation.
18. The energy storage system of claim 17, wherein at least a
portion of the carriers are configured to discharge the mass medium
carried thereby onto at least one of the first mass pile area and
the second mass pile area.
19. The energy storage system of claim 17, wherein the first mass
pile comprises at least one of dirt, sand, rock, mine tailings,
gravel, or other similar native or naturally occurring
material.
20. The energy storage system of claim 17, wherein the system is
configured to provide at least one of bulk energy storage, bulk
energy generation, frequency regulation, a combination of bulk
energy storage and frequency regulation, and a combination of bulk
energy generation and frequency regulation.
21. The energy storage system of claim 1, wherein the first mass
pile comprises at least one of dirt, sand, rock, mine tailings,
gravel, or other similar native or naturally occurring material.
Description
BACKGROUND OF THE DISCLOSURE
1. Field of the Disclosure
The present disclosure relates to energy storage devices, in
particular, energy storage devices configured to provide fast
response ancillary services and/or bulk energy storage which may be
used with large scale electricity grids.
2. Background of the Disclosure and Description of the Related
Art
The electricity power grid has little means of storing energy.
Therefore, the amount of electricity generated should
instantaneously match demand as closely as possible. Despite
efforts to supply the power grid with the electricity that
precisely matches the instantaneous demand, the actual power
provided to the grid often exceeds or falls short of the actual
power demand at any given moment, causing deviations in the
frequency, away from the target operating condition, of the
alternating current of the electricity grid. There is therefore a
need for a system for rapidly absorbing energy from and outputting
energy to the grid.
Likewise, due to dramatic changes in the demand for electricity
over a typical 24 hour period, it is necessary for a grid operator
to dispatch and curtail electricity generation assets to match the
changes in demand. The time difference between minimum and maximum
demand can be as long 12 hours. Therefore, a bulk energy storage
device, being defined as a device which can produce megawatts of
power, sufficient for participating in the electricity grid, and
can operate for several hours in duration when either consuming or
producing electricity, is needed to manage these large swings in
electricity demand.
SUMMARY OF SOME EXAMPLE EMBODIMENTS
Some embodiments of the present disclosure relate to novel energy
storage systems and methods which can be used to address several
energy storage markets and needs, spanning from fast response
ancillary services to bulk energy storage. The energy storage
devices of the present disclosure can provide support for the
stable operation of the electrical grid by storing and then
releasing large amounts of energy.
In some embodiments, the energy storage devices can comprise a
plurality of cables or loops of cables that can be positioned
adjacent to one another to form an array of cable loops. In some
embodiments, the cable loops can be stretched between two
bullwheels, from which hooks or carriers can be supported. The
hooks or carriers can be used to transport weights from a higher to
lower elevation to generate electricity, or from lower to higher
elevation to store electrical energy. The overall capacity of the
storage installation can be changed by either increasing the
weights of any one cable loops, or by increasing the number of
cable loop systems in an installation.
In some embodiments, electricity can transferred to and from the
electrical grid through a set of power electronics connected to an
electric motor/generator. The electric motor can be connected to
the bullwheel, located at one end of the cable. The rotation of the
bullwheel can cause the cable to translate, pulling the hooks or
carriers in one direction or the other (e.g., either uphill or
downhill) depending on whether energy is stored or generated. The
movement of the carriers, with attached weights or masses, can
cause the weights/masses to be raised or lowered, which can either
store or generate electricity due to the gravitational forces on
the masses. The velocity of the moving weights or masses can allow
energy to be stored as kinetic energy as well.
The energy can be stored both through the gravitational potential
of raising weights as well as the kinetic energy of the velocity of
the weights. In some embodiments, the weights can have of a
low-cost shell, such as molded cement, metal, injected plastic, or
other material, filled with low-cost gravel, rocks, or soil. In
some embodiments, where the mass is configured to be rolled (for
example, within a storage container) during handling, the shell can
help maintain the rounded shape, such as the shape of a cylinder or
sphere. When energy is needed to be generated, a weight will be
picked up from the storage container at higher elevation and can be
loaded onto the cable system. As weights reach the bottom of the
cable system, they can be removed and stored within the lower
storage container. Likewise, the process can work in reverse to
store energy--weights can be removed from the lower storage
container and be deposited in the higher storage container.
Some embodiments disclosed herein relate to an energy storage and
generation system, comprising a cable system having a first end
portion located at a first elevation and a second end portion
located at a second elevation, a plurality of mass carriers
supported by the cable system, one or more motor generators coupled
with the cable system and with an energy grid, a control system in
communication with at least the one or more motor generators, a
first mass pile area configured to store mass medium positioned at
the first elevation, and a second mass pile area configured to
store mass medium positioned at the second elevation that can be
higher than the first elevation. In some embodiments, the one or
more motor generators can be configured to move the cable system in
an energy storing state and be configured to be moved by the cable
in an energy generating state so as to produce energy to the energy
grid. The system can be configured to cause energy to be stored by
transferring mass medium from the first mass pile area to the
second mass pile area. The system can be configured to cause energy
to be generated by the one or more motor generators of the energy
storage system by transferring mass medium from the second mass
pile area to the first mass pile area. In some embodiments, the
system can further comprise program code stored in memory that, if
executed by a computing system, causes the computing system to
perform operations comprising receiving an offer to purchase energy
from a first entity, receiving information regarding energy pricing
from at least one source, and, based at least in part on the offer
from the first entity and the energy pricing information,
determining whether to generate energy.
Some embodiments or arrangements disclosed herein relate to a
method of storing energy and/or supplying energy to a power grid
using an energy storage device, comprising moving a plurality of
carriers from a first elevation to a second elevation and/or from a
second elevation to a first elevation, wherein the second elevation
is higher than the first elevation, and transferring mass medium
from the first elevation to the second and/or from the second
elevation to the first elevation using the plurality of carriers.
Transferring more mass from the first elevation to the second
elevation than from the second elevation to the first elevation can
cause the energy storage device to store energy received from the
power grid. Transferring more mass from the second elevation to the
first elevation than from the first elevation to the second
elevation can cause the energy storage device to generate energy,
wherein at least a portion of the generated energy is supplied to
the power grid.
Some embodiments or arrangements disclosed herein relate to a
method of controlling an energy storage device, comprising
receiving over a network a communication regarding a request for or
a price to be paid for frequency regulation with respect to a power
grid, based at least in part on a payment offered with respect to
supplying at least a portion of the requested frequency regulation,
determining whether to provide at least the portion of the
frequency regulation, if a determination is made to provide at
least the portion of the frequency regulation, causing material to
be raised from a first level to a second level to thereby consume
power from the power grid, wherein the material is primarily a
non-liquid, then causing the primarily non-liquid material to be
lowered from the second level to the first level to thereby provide
power to the power grid. In some embodiments, the raising and
lowering of the primarily non-liquid material enhances the
frequency regulation of the power grid.
Some embodiments or arrangements disclosed herein relate to a
method of controlling an energy storage device. The method
comprising the steps of storing energy during a first period of
time, performing frequency regulation during a second period of
time, and producing electricity for the power grid during a third
period of time, all three stages occurring in sequence over the
course a day. The process of storing energy during the first period
of time preferably comprises the steps of: receiving electricity
from the power grid; raising a solid ballast from a lower elevation
to higher elevation (preferably greater than 100 meters) using the
received electricity; receiving over a network a command to either
produce electricity for the power grid or consume electricity from
the power grid; varying the amount of received electricity in
accordance with the command; and varying the rate at which solid
ballast is raised from a lower elevation to higher elevation using
the received electricity. The process of performing frequency
regulation during a second period of time preferably comprises the
steps of: receiving over a network a command to either produce
electricity for the power grid or consume electricity from the
power grid; and varying the amount of electricity received from or
provided to the grid by alternating, respectively, between raising
and lowering the solid ballast between the lower elevation and
higher elevation in accordance with the command. The process of
producing electricity for the power grid during a third period of
time preferably comprises the steps: providing electricity to the
power grid; lowering the solid ballast from the higher elevation to
the lower elevation to generate the provided electricity; receiving
over a network a command to either produce electricity for the
power grid or consume electricity from the power grid; varying the
rate at which solid ballast is lowed from the higher elevation to
the lower elevation; and varying the amount of provided electricity
in accordance with the command.
During the first period of time, the energy storage device is
configured to only transport the ballast uphill by continuously
loading solid ballast at the lower elevation and unload the ballast
at the higher elevation. During the third period of time the energy
storage device may transport ballast uphill or downhill. During the
third period, the energy storage device is configured to only
transport ballast downhill by continuously loading solid ballast at
the lower elevation and unload the ballast at the higher elevation.
During the second period of time, the energy storage device is
configured to quickly alternate between storing energy and
producing energy, or producing energy and storing energy, in the
scale of 1 and 10 seconds.
The energy storage device may comprise a plurality of cables, each
cable configured to transport solid ballast between the higher and
the lower elevation. The energy storage device may vary the
quantity or speed of the ballast transported between the lower and
the higher elevation based on the amount of electricity to be
retrieved from or provided to the power grid. In addition, the
different cables may be operated at different speeds from one
another and/or transport different amounts of ballast from one
another in order to optimize performance.
BRIEF DESCRIPTION OF THE DRAWINGS
The drawings are provided to illustrate example embodiments
described herein and are not intended to limit the scope of the
disclosure.
FIG. 1A is a graphical representation of electricity prices, state
of charge of some embodiments of energy storage devices disclosed
herein, and power generation and consumption of some embodiments of
energy storage devices disclosed herein over a 24 hour period.
FIG. 1B is a graphical representation of the operational modes of
an example energy storage device, the operation modes corresponding
to various energy-related services offered by the energy storage
device;
FIG. 2A is a side view of an example embodiment of an energy
storage device.
FIG. 2B is a side view of another example embodiment of an energy
storage device.
FIG. 3A is a first schematic representation of an example
embodiment of an energy storage device.
FIG. 3B is a second schematic representation of an example
embodiment of an energy storage device.
FIG. 4 is a side view of an example embodiment of an energy storage
device.
FIG. 5A is a side view of an example embodiment of an energy
storage device.
FIG. 5B is a top view of the example embodiment of the energy
storage device illustrated in FIG. 5A.
FIG. 6 is a top view of an array of example energy storage device
embodiments.
FIG. 7A is an illustration of an example embodiment of an energy
storage device, showing the energy storage device in an energy
storage or charging mode.
FIG. 7B is an illustration of the example embodiment of an energy
storage device shown in FIG. 7A, showing the energy storage device
in an energy generating mode.
FIG. 8A is an illustration of an example embodiment of an energy
storage device, showing the energy storage device in an energy
storage or charging mode.
FIG. 8B is an illustration of the example embodiment of an energy
storage device shown in FIG. 8A, showing the energy storage device
in an energy generating mode.
FIG. 9 is a side view of another example embodiment of an energy
storage device.
FIG. 10 is an enlarged view of a portion of the example embodiment
of the energy storage device illustrated in FIG. 9.
FIG. 11A is an enlarged view of a portion of the example embodiment
of the energy storage device illustrated in FIG. 9.
FIG. 11B is an enlarged view of a portion of another example
embodiment to the loading portion of the embodiment of the energy
storage device illustrated in FIG. 9.
FIG. 12A is a perspective view of the example embodiment of the
energy storage device illustrated in FIG. 9, taken from an upper
view, showing the path of movement of a first loop of the cable
system.
FIG. 12B is a perspective view of the example embodiment of the
energy storage device illustrated in FIG. 9, taken from an upper
view, showing the path of movement of a second loop of the cable
system.
FIG. 13 is a perspective view of the example embodiment of the
energy storage device illustrated in FIGS. 12A and 12B, taken from
an upper view.
FIG. 14 is a perspective view of the example embodiment of the
energy storage device illustrated in FIG. 9, taken from a lower
view, showing the path of movement of a first loop and a second
loop of the cable system.
FIG. 15 is a perspective view of a plurality of example energy
storage devices arranged about a hillside.
FIG. 16 is a perspective view of an example trigger or tipping
mechanism that can be used to activate the discharge of the medium
carried by the carriers.
FIG. 17 is a side view of an example container for a plurality of
masses having at least one round surface.
FIG. 18 is an example plot showing a first response to actual
frequency regulation data from a grid operator.
FIG. 19 is an example plot showing a second response to actual
frequency regulation data from a grid operator.
FIG. 20 is an example plot showing a third response to actual
frequency regulation data from a grid operator.
FIG. 21 is an example graphical representation of a simulation of
actual power output, desired power output, and height.
FIG. 22 is an example graphical representation of a response of a
simulated energy storage device to actual power grid data, in
particular, an actual PJM frequency regulation signal.
FIG. 23 is an example graphical representation of a response of a
simulated energy storage device to actual power grid data, in
particular, an actual PJM frequency regulation signal.
FIG. 24 is another example graphical representation of a response
of a simulated energy storage device to actual power grid data, in
particular, an actual PJM frequency regulation signal.
FIG. 25 is an example graphical illustration of a sample of power
grid step change increments.
FIG. 26 is a flow chart of the method of energy management
according to one example embodiment.
DETAILED DESCRIPTION OF SOME EXAMPLE EMBODIMENTS
The electricity grid has little means of storing energy. Without
such storage solutions, conventionally the amount of electricity
generated must instantaneously match demand. Conventionally, this
has been a difficult goal to achieve. Further, conventional
techniques for the mass storage of energy, such as hydro-based
techniques involving the movement of water from one level to
another, have often been impractically expensive, require
geographical conditions that are rare or expensive to create (e.g.,
large upper and lower reservoirs for holding the water), and may
involve a significant level of risk (e.g., in the case of
hydro-based techniques, flooding risks in the event of a reservoir
dam failure, heavy rainfalls, earthquakes, etc.).
By contrast, certain embodiments disclosed herein provide services
that can efficiently address the need for bulk energy storage via
certain grid-scale energy storage device embodiments and/or can
provide substantially instantaneous power or consummation of power
in order to aid in power regulation of the power grid. Further,
certain embodiments access data with regards to requests for bulk
power or power regulation (e.g., via pricing data or signals or
otherwise), determine (based on one or more criteria) the
advisability of providing such bulk power and/or power regulation,
and then provide (or not provide) such bulk power or power
regulation in accordance with such determination.
"Bulk Energy" corresponds to the unit of energy which is at least
one megawatt of power, with a duration of at least one hour (either
being consumed or produced). "Bulk Power" is defined as at least
one megawatt of power. This distinction is important to
differentiate certain example embodiments from non-bulk energy
storage devices (although other embodiments may be in the form of
non-bulk energy storage devices). These would include devices which
can consume or produce megawatts of power, but can only operate
continuously for a few minutes without recharging (such as typical
flywheels, super-capacitors, some battery systems), or devices
which can last several hours, but cannot produce megawatts of power
(e.g., other battery systems), or embodiments disclosed herein that
have relatively little mass available to transport.
Typically, there are three major ancillary services that can be
provided to the grid, in addition to just selling bulk energy or
electricity. The three are often referred to as non-spinning
reserve, spinning reserve, and frequency regulation. All or a
subset of the three such services can be provided by the energy
storage device embodiments disclosed herein. Frequency regulation
can, in many instances, be the most lucrative. The term
"non-spinning reserve" refers to a power generator that is
completely shut off (the shaft is not spinning). However, if
needed, the power generator can be activated and conventionally can
start providing power in approximately 30 minutes. Because the
generator is merely sitting idle, this service is paid the least.
The next is term, "spinning reserve" refers to a generator that is
on, and spinning, but is producing no electricity. The generator is
merely idling, consuming minimum fuel, but can produce power very
quickly. Conventionally, such idling generators can sometimes be
activated to provide power in 10 minutes. Because of the quicker
response time, this service is typically paid more. "Frequency
regulation" requires a generator to respond to a signal within
seconds, and is the highest paid service of the three. All three of
these services can be provided with at least some of the
embodiments disclosed herein.
Some embodiments of the present disclosure are directed to an
electricity storage device which can be used for any of the
above-mentioned applications or functions. Depending on which
application is chosen may determine some of the overall design
parameters, but the system architecture is applicable to all
applications. Some embodiments of the present disclosure store
electrical energy as both gravitational potential energy and
kinetic energy when there is a surplus of power on the grid. Then,
the kinetic and potential energy is converted back to electricity
when the there is excess demand on the grid. As described herein,
at least some embodiments of the energy storage device disclosed
herein perform at least three functions important to energy grids:
charging, discharging, and providing frequency regulation.
Regarding charging, while certain embodiments of the system may not
store electrical "charge," per se (although certain embodiments may
include electrical storage devices, such as large scale battery
farms), the notion of "charging" the energy storage device like a
battery is a useful analogy. "Charging" the system refers to
converting input energy into a stored form to be recovered later.
Some embodiments of the energy storage device can be said to be in
a fully charged state when no more energy can be stored, and in a
fully discharged state when no more energy can be extracted from or
generated by the system.
FIG. 1A is a graphical representation of example electricity
prices, state of charge and operational modes of some embodiments
of energy storage devices disclosed herein, and power generation
and consumption of some embodiments of energy storage devices
disclosed herein over a 24 hour period. When the system is
scheduled for charging, (e.g., as determined through market data
received from the grid operator, as discussed elsewhere herein,
and/or via a pre-arranged agreement to charge and supply power),
some embodiments of the control system can be configured to send a
signal to a power electronics module to begin drawing power, in the
form of electricity, from the grid. This electricity can be used to
drive an electric motor, which can be configured to drive a shaft
or other mechanism that can rotate a hoist or, as described with
reference to some of the embodiments, the motor can pull a cable
over a pulley system.
In these example configurations, a cable attached to the hoist or
running over the pulley system can raise a mass from a lower
elevation to a higher one, thereby converting the electrical energy
to mechanical energy, and then to gravitational potential energy.
In some embodiments, the height difference between the upper
elevation position and the lower elevation position can be between
approximately 400 feet (121.92 meters) and 600 feet (182.88
meters). However, some embodiments of the energy storage system may
be suitable for smaller or larger elevation changes. Additionally,
slopes having an angle of 30 degrees, or greater or lower angles,
may be used for the energy storage devices. Certain embodiments use
substantially naturally occurring slopes of about 30 degrees or
within the range of 25 degrees to 35 degrees. However, as
mentioned, any suitable angle, slope, or cliff can be used. For
example, an angle of about 10 degrees, 45 degrees, or 90 degrees
can be used. In many situations, the steeper the angle, the better
the energy storage capacity (assuming the amount of mass being
moved is constant). However, naturally occurring geographic
features (e.g., cliffs) of sufficient height and at a very steep
(e.g., 90 degrees) angle may be substantially rarer than naturally
occurring geographic features (such as hillsides) at lesser
angles.
When the system is scheduled for discharging (e.g., as determined
through market data received from the grid operator and/or via a
pre-arranged agreement to charge and supply power), the control
system can be configured to send a signal to the power electronics
module to begin sending power to the grid. In operation, this can
be achieved using the following example process. The control system
can cause the mass to descend from one elevation to another, lower
elevation, thereby converting gravitational potential energy in the
mass to mechanical energy that can rotate or otherwise work the
motor/power generator and thereby generate electricity. The
motor/power generator can be connected to the cable via the hoist,
pulley, and/or cable (which may be in the form of a fabric cable,
rubber cable, stranded metal cable, chain cable, or other type of
cable). The electricity can be converted in the power electronics
module or other suitable component to the correct conditions
necessary for the grid.
Regarding frequency regulation, when the energy storage device is
scheduled or configured for providing frequency regulation, in some
embodiments, the control system can receive a signal from the grid
operator as to what the level of instantaneous requested power is.
This signal can come in the form of a percent of maximum power
capacity available for frequency regulation or can be specified as
specific energy unit(s). The control system can send a signal
indicating to the power electronics module the desired power (e.g.,
the optimal desired power) to produce so as to most closely match
the grid operator request or so as to match the grid operator
request within a tolerance specified by the grid operator or other
entity. This desired power level may be a function both of the
requested power and the current system operating conditions (state
of charge, mass velocity and acceleration, as well as other
parameters in certain instances).
One non-limiting example of a calculation used to determine the
desired power level is discussed below, and is identified as the
"Desired Power Level Calculation." Based on this signal, the power
electronics module can either command the system to consume or
produce power, as specified in the charging and discharging
descriptions above. As the system parameters change, with respect
to the commanded signal, the control system can calculate a new
desired power level to substantially continually adjust to the
changing signal from the grid, and the changing system conditions
of the device.
One difference between at least some embodiments of this disclosure
and existing conventional suppliers of frequency regulation is the
ability of some embodiments of the energy storage device to quickly
provide frequency regulation service during periods where the
energy storage device is neither currently charging nor
discharging, as well as the ability to earn revenue from providing
energy arbitrage. For example, certain conventional hydroelectric
dams can provide frequency regulation service while producing
electricity. However, during times that the dam is not producing at
least a substantial amount of bulk power, it typically cannot
provide regulation services either.
Likewise, for coal plants and natural gas generators, they can only
provide frequency regulation when they are producing power using a
substantial percentage of their capacity. It takes a substantial
amount of time for such coal plants and natural gas generators to
start producing power ("come online") from a quiescent ("off")
state, and it is not economical or efficient to run such coal
plants and natural gas generators at less than a high percentage of
their capacity or outside their design range, and therefore
operating at less than near full capacity uses more fuel (per
amount of energy produced), increases maintenance costs, and
reduces lifetime. On the other hand, conventional flywheel storage
technology (where energy is stored as the kinetic energy of the
flywheel disk) can provide frequency regulation service
continuously (as they offer a quick response time), but because of
the small amount of energy that they store, they cannot earn
revenue by providing energy arbitrage, that is, they cannot produce
large amounts of power for a substantial period of time. Any of
these technologies can be used in conjunction with the example
embodiments of the energy storage devices disclosed herein.
At least some energy storage device embodiments disclosed herein
are unique in that such embodiments can provide frequency
regulation continuously, like a flywheel, yet also produce bulk
energy, earning energy arbitrage revenue (e.g., where energy may be
purchased via the grid and stored during an off-peak period, when
energy is relatively less expensive, and then sold to the grid
during peak periods at a higher price, to thereby generate net
revenues), like a natural gas or coal generator.
During a given period (e.g., a 24 hour period), any of the energy
storage device embodiments disclosed herein may be subjected to
several operational modes, including, without limitation, an
off-peak mode, a mid peak mode, a peak mode, and, again, a mid peak
mode. During the off-peak mode (e.g., such as when people tend to
be asleep and businesses tend to be closed), electricity prices are
generally the lowest. The energy storage device can be configured
to purchase electricity during this mode and to convert the input,
low cost energy to gravity-based potential energy, up to the
maximum storage capacity of the device. During this time, if
economically beneficial, some portion of the charging capacity can
be allocated to provide frequency regulation services to the
grid.
During the mid peak mode, electricity prices are generally not at
their peak. Because of the design of certain embodiments, the full
power capacity of the energy storage device can be offered as
frequency regulation services. This is different from the
capability of pumped hydro, compressed air energy storage, or other
generation technologies, which generally cannot offer frequency
regulation unless they are also generating electricity as a
sufficient baseline for efficient plant operation (which may be at
a substantial portion of their capacity). Frequency regulation, on
average, does not substantially produce or consume a net amount of
energy over a given time period and thus the amount of energy
stored at the end of the midpeak period is equal to the amount of
energy stored at the end of the offpeak period, minus system
losses.
During the peak energy mode (e.g., when people are consuming peak
amounts of energy, such as when they are awake, working, and
heating or cooling their workplaces or residences), electricity
prices are generally at the highest level. The energy storage
device can be configured to produce power through conversion on the
stored potential energy to electricity. This electricity can then
be sold to the grid. If economical, any of the storage device
embodiments disclosed herein energy can also provide frequency
regulation service during this period. Returning again to mid peak
mode, the final midpeak period is similar to the first midpeak
period, in that the energy storage device can be configured to
provide frequency regulation services for its full power capacity
during this time.
In embodiments disclosed herein, mass used for the energy storage
device can be a solid material such as rock, gravel, dirt, sand,
pulverized asphalt or concrete, mine tailings, ice, snow, water,
snow, ice and/or any other man-made or natural occurring material
or substance. Wind and rain may cause dust, dirt, sand, water,
and/or constituents to be added to one or more mass piles or to the
mass generally. Therefore, in some embodiments, the mass used for
the energy storage device can be a combination of materials and/or
substances, and may not be free from moisture. Accordingly, in some
embodiments, the mass pile can comprise primarily rock, gravel,
dirt, sand, pulverized asphalt or concrete, mine tailings, and a
combination of the foregoing.
For example, the mass pile can comprise approximately 95% or more
by weight of at least one of dirt, gravel, sand, rock, and a
combination of the foregoing. In some embodiments, the mass pile
can comprise approximately 85% or more by weight of at least one of
dirt, gravel, sand, rock, and a combination of the foregoing. In
some embodiments, the mass pile can comprise approximately 75% or
more by weight of at least one of dirt, gravel, sand, rock, and a
combination of the foregoing. In some embodiments, the mass medium
can be primarily a non-liquid. For example, the mass medium can be
approximately 95% or more by weight non-liquid, approximately 90%
or more by weight non-liquid, approximately 80% or more by weight
non-liquid, approximately 70% or more by weight non-liquid, or
otherwise.
Economical materials, such as those already existing at a site or
location, may be preferred from a cost standpoint. For example, at
certain sites, rock, gravel, dirt, and/or mine tailings may be
locally available. Such solid material (also referred to herein as
mass medium or just medium) can be transported from one elevation
to another to store and generate energy. In some embodiments, the
solid material can be attached to or supported by a cable, bucket,
container or other carrier. A haul rope, cable, and/or a system of
pulleys can be used to transfer the kinetic energy of the moving
masses to an electric motor/generator. In some embodiments, the
motor/generator can be reversible. This near-rigid transfer of
power from the mass to the haul rope to the pulleys to the
generator can result in the transfer energy with high roundtrip
efficiency. Advantageously, in contrast to hydro-energy storage
systems, certain embodiments do not require water reservoirs
configured to hold water to be raised or lowered in order to
produce power. Indeed, certain embodiments do not require the
movement of large volumes of water in order to produce power at
all.
To improve the appropriateness and efficiency of the energy storage
device for bulk energy storage, it may be beneficial to size the
amount of weight being stored to be sufficiently large. Likewise,
to improve the applicability and efficiency of the energy storage
device to serve the frequency regulation market, it may be
beneficial to configure the control system and power electronics to
allow for rapid charging and discharging to the grid.
FIG. 1B is a representation of different operating modes that will
typically be followed by some embodiments of the energy storage
devices disclosed herein. As also illustrated in FIG. 1A, the
typical modes of operation for certain example embodiments will
take advantage of periodic price shifts in the electricity market.
While a 24 hour cycle is very common, embodiments disclosed herein
also applicable to any electricity market that has periodic price
swings (with a period that is different than 24 hours).
The baseline operation during this period, and that which provides
bulk energy storage, is to completely charge (or charge at other
significant levels of capacity) an energy storage device during
periods of low electricity prices and to discharge completely (or
discharge other significant levels of capacity) during high
electricity prices. These modes are labeled the "Charging" and
"Discharging" periods.
Layered on top of this operation is the ability to provide
frequency regulation to the grid. A portion of the power capacity
of the device (either while charging or discharging) can be
allocated to frequency regulation. The allocation between frequency
regulation and bulk charging/discharging may, in certain
embodiments, depend on both the prices for frequency regulation and
the prices for electricity. However, during periods where the
storage device is neither charging, nor discharging (labeled
"Midpeak" in FIG. 1A), certain embodiments of the storage device
can provide up to twice its maximum power capacity as frequency
regulation. These modes are labeled the "Frequency Regulation"
period.
In addition, it is possible that there are periods where neither
charging/discharging, nor frequency regulation are economic or
otherwise desirable. During these periods, neither
charging/discharging or frequency regulation will be performed.
These periods are labeled "Transition".
Finally, separate from any of these operations, certain embodiments
of the storage device can offer to provide other ancillary
services, such as non-spinning reserve, spinning reserve, and
others. In certain embodiments, these services may be additional to
any of the above activities, and some or all of these ancillary
services may be offered as long as sufficient power capacity from
the device is reserved. Due to typical pricing structures of
electricity and frequency regulation, the amount of other ancillary
services provided by the storage device will be secondary in
certain example embodiments. These additional ancillary services
are represented by the label "Spinning Reserve".
In certain embodiments, the decision as to when each mode starts
and ends, transitioning into the following mode, is made by
examining a number of factors to predict market pricing. In markets
where market pricing is not transparent, the operation of certain
embodiments of the storage device, through some or all of these
various modes, may be set by the grid operator/electric
utility.
An example or embodiment of an energy storage device 100 is
illustrated in FIG. 2A, the energy storage device 100 having a mass
102, a hoist 104 (which can also be or have a pulley), and a cable
106. FIG. 2B is a side view of another embodiment of an energy
storage device 120. FIGS. 3A and 3B are schematic representations
or flow charts of some of the components that can comprise some
energy storage device embodiments disclosed herein, including
without limitation the embodiment of the energy storage device 100
illustrated in FIGS. 2A and 2B.
The cable 106 can be a rope, chain, steel cable, or any other
similar appropriate material or object capable of providing tensile
support to the mass or masses 102 that can be moved from one
elevation to another. In the illustrated example embodiment, the
energy storage device 100 is configured such that mass 102 can be
supported by an end portion of the cable 106, but is otherwise only
subjected generally to the force of gravity (g) (and possibly
wind). The hoist 104 can be configured to alter the direction of
the cable 106 and can provide a guide mechanism for the cable
106.
The energy storage device 100 can also have a motor/power generator
108 in communication with the cable, the power generator 108 being
configured to raise the level of the mass 102 to store energy (in
the form of potential energy). As described, the power generator
108 can be configured to draw power from the energy grid in order
to raise the mass 102 during off-peak energy consumption periods of
time (or at other times, as desired). The energy storage device 100
can also be configured to produce energy to the grid by permitting
the mass 102 to fall or be lowered, thereby creating kinetic
energy. The power generator 108 can generate energy that can be fed
into the energy grid as the mass 102 is falling and producing
kinetic energy. The energy produced by the energy storage device
100 can be fed into the grid during, for example and without
limitation, periods of peak energy consumption.
The motor/power generator 108 can be attached to an end of the
cable 106, or the cable can form a continuous loop around the hoist
104, around a pulley within or powered by the power generator 108
and to the mass 102, if, for example, another pulley or hoist 104
were positioned beneath the mass 102. Alternatively, the power
generator 108 can be positioned or configured to be in direct
contact with the hoist 104. Some embodiments, this can be achieved
by coiling the length of the cable 106 either helically or
otherwise around the hoist or pulley 104.
The energy storage device 100 may include a control system 110
configured to control the motor/power generator 108 and, hence, the
position, speed, and direction of motion of the mass 102 and,
accordingly, whether energy is being stored or generated and the
magnitude of the energy being stored or generated. The control
system 110 can have electronic and/or manual controls to control
the motor/power generator 108 and/or can be pre-programmed with
computer software or algorithms for such control. The motor/power
generator 108 can be connected to a power electronics module 112
that can convert the electricity produced by the motor/power
generator 108 into a form that is suitable for feeding into the
power grid.
Additionally, in some embodiments, the energy storage device 100 or
any other energy storage device embodiment disclosed herein can
have one or more sensors 111 that can provide data signals or other
feedback or information to the control system 110, to a user
through a display or otherwise, to a data recorder, or to an alarm
system, or otherwise. For example, without limitation, the sensors
111 can be configured to monitor line velocity, acceleration, or
direction, mass on the line or in particular carriages, total mass
in a storage location, spacing between removable or non-removable
masses or any other desired system parameters.
As mentioned, FIG. 2B is a side view of another embodiment of an
energy storage device 120. In some embodiments, with reference to
FIG. 2B, the mass 122 can be supported on an angled surface (having
an angle A), such as the support surface 132 illustrated therein.
In this configuration, the mass can be connected to a cable 126
that is routed over a pulley 124. The cable 126 can be connected at
the other end to a motor/power generator 128 (not illustrated)
which can be controlled by a control system (130). The support
surface can be positioned along an angled surface, which can be a
naturally occurring hill or other slope, and can be configured to
provide a smooth, low friction weight-bearing surface to the mass
122. Additionally, in some embodiments, the mass 122 and/or support
surface 132 can have wheels or rollers thereon to limit the
friction, resistance, or other energy loss when the mass 122 is
moved either up or down the support surface 132.
Referring again to FIGS. 3A and 3B, as illustrated in FIG. 3A, and
as similarly described elsewhere herein, based on one or more
inputs (e.g., a preprogrammed schedule, a request for bulk power or
frequency regulation from a power grid operator, etc.) a controller
110 controls an electric motor/generator 108 and optionally a
separate braking mechanism (not shown), to control the hoist 104 to
change the elevation of the mass(es) 102. The controller 110 may
receive feedback from the motor/generator (e.g., the amount of
power being generated or consumed, the motor RPM, etc.). When
operating in a power generation mode (when lowering the mass(es)
102), the motor/generator 108 provides power to power electronics
112, which is then output to the grid. When operating in a power
storage mode (when raising the mass(es) 102), the motor/generator
108 receives power from power electronics 112 which the power
electronics 112 receives from the grid.
FIG. 3B illustrates the flow of electricity, information, and the
mechanical flow with respect to the system 100. As illustrated, a
grid operator transmits (e.g., from a computer system associated
with the grid operator, over a network, such as the Internet, to a
computer system associated with or included in the system 100) a
request for power/electricity or frequency regulation to the
control system 110. The request may include a price being offered
for units of power and/or for an amount of frequency regulation.
The offer may specify a minimum and/or maximum amount of power to
be supplied and/or a tolerance range for the frequency regulation.
If frequency regulation is being provided by the device, the
information from the grid operator may include the required or
requested changes in power consumption/production during the period
in which frequency regulation is being provided. In addition, the
control system 110 may access electricity market data (e.g., the
amount being charged and/or offered for power or frequency
regulation for different periods of time, such as at peak,
mid-peak, and off peak periods of time). Optionally, in addition to
or instead of receiving a request from the grid operator, the
process may monitor (via one or more data feeds received over the
network from one or more data sources) historical, current and/or
anticipated future prices of energy, frequency regulation, spinning
reserves and/or non-spinning reserves. The control system 110 may
utilize the market data to determine whether or not to generate or
store energy and/or whether or not to perform frequency regulation
(and/or other ancillary services) in accordance with the request
and/or in response to the data monitoring. The control system 110
may transmit an acceptance of the offer or a refusal to the grid
operator or may supply energy and/or ancillary services without
transmitting over the network an acceptance or refusal.
The control system 110 may operate the motor 108 and the power
electronics 112 as similarly discussed above with respect to FIG.
3B. The motor/generator 108 raises or lower the mass(es) 102 to
thereby store or generate electricity, as described above. To
improve control, the device may use additional system sensors 114
including some or all of the following: a tension sensor to measure
the tension on the line or cable (which may provide an indication
as to the total mass on the line), a mass sensor to determine the
mass of each bucket, mass sensors to measure the quantity of
material stored in the pile, position sensors to confirm the
position of the weights during loading and unloading, as well as
position sensors to determine the valve opening position, and force
sensors to monitor the force needed to open or close the valve for
dispensing material into the buckets.
FIG. 4 is a side view of an embodiment of an energy storage device
160. In some embodiments, with reference to FIG. 4, one or more
masses 162 (one being shown) can be supported by a cable system 166
supported along a sloping surface or hillside by a first tower 169a
and a second tower 169b. The first tower 169a can be positioned at
a lower elevation than the second tower 169b. A second cable or
cable system 171 can be routed over one or more pulleys or guide
wheels 164 (one being shown) supported by one or more support
towers or support members 173 positioned at the top of the slope or
along the slope. The second cable 171 can be connected to the
motor/power generator 168 such that, when the operator of the
energy storage device 160 desires to store energy in the energy
storage device 160, the motor 168 retracts the second cable 171 and
the mass 162 in a first direction from a lower to a higher
elevation to increase the potential energy of the mass 162 and,
hence, the energy storage device 160. In contrast, when the
operator of the energy storage device 160 desires to produce energy
to the grid, motivating power to the motor 168 can be ceased
(although power may still be applied for control and monitoring
electronics and sensors) and the mass 162 can be permitted to
descend down the slope toward the first tower 169a due to the
gravitational force exerted on the mass 162. Allowing the mass 162
to descend down the slope will cause the second cable 171 to work
the motor/power generator 168 and produce electricity. Optionally,
the motor 168 or other breaking mechanism may be used to slow or
control the descent to a safe velocity or acceleration.
FIGS. 5A and 5B are a side view and a top view, respectively, of an
embodiment of an energy storage device 180. In some embodiments, as
illustrated in FIGS. 5A and 5B, one or more masses 182 (one being
shown) can be removably or non-removably supported by a cable
system 186 supported along a sloping surface or hillside by a first
pulley 184a (also referred to as a bullwheel or a drive bullwheel)
coupled to motor/generator 188, and a second pulley 184b (also
referred to as a bullwheel or a return bullwheel). In some
embodiments, a plurality of masses 182 can be supported along
one-half the length of the cable 186 or along one side of the cable
186. In some embodiments, a plurality of masses 182 can be
supported (removably or otherwise) along the entire length of the
cable 186. Additionally, in some embodiments, the masses 182 can be
mass carriers configured to selectively carry a transportable mass
from the lower to the higher elevation, or vice versa. In such a
configuration, the energy storage device 180 can have a plurality
of mass carriers continuously or at uniform or non-uniform
intervals along the cable 186.
The cable system 186 can be routed over a plurality of smaller
pulleys or guide wheels 185 supported by one or more support towers
or support members 189 positioned along the slope. The first
bullwheel 184a can be positioned at a lower elevation than the
second bullwheel 184b. The second bullwheel 184b can be connected
to the motor/power generator 188 such that, when the operator of
the energy storage device 180 desires to store energy in the energy
storage device 180, the motor 188 rotates the second bullwheel 184b
in a first direction that causes the mass 182 to be pulled up the
slope to increase the potential energy of the energy storage device
180, as illustrated in FIG. 7A (showing multiple masses 182). For
some embodiments disclosed herein, using multiple masses, as
illustrated in FIG. 7A, can permit more total mass to be used,
optionally in smaller, easier to handle units, increasing the
amount of energy that can be stored in an energy storage device,
while reducing the structural requirements of the energy storage
device and the device holding the masses (e.g., gravel or sand
containers). In some embodiments, the masses can be located along
only one side of the cable, the cable direction being reversible.
In some embodiments, the cable can be operated in a single
direction during some or all of the operation, such that the masses
switch sides during operation.
In contrast, when the operator of the energy storage device 180
desires to produce energy to the grid, power to the motor 188 can
be ceased and the mass 182 can be permitted to descend down the
slope toward the first bullwheel 184a due to the gravitational
force exerted on the mass 182, as illustrated in FIG. 7B.
Optionally, the motor 188 or other breaking mechanism may be used
to slow or control the descent to a safe velocity or acceleration.
Allowing the mass 182 to descend down the slope will cause the
cable system 186 to exert a torque on the second bullwheel 184b,
thereby working the motor/power generator 188 and producing
electricity. Any of the energy storage device embodiments disclosed
herein, including the energy storage device 180, can be configured
for use along any desired slope, even a slope that is near or equal
to a vertical pitch, or any slope between vertical and horizontal
pitches such as between approximately thirty degrees and
approximately forty degrees, without limitation. Steeper slopes may
provide performance and efficiency benefits. In some embodiments,
the masses can be rotated all the way around the loop of cable such
that fewer or no directional changes would be required.
FIG. 6 is a top view schematic illustration of a plurality of
energy storage devices 180, each supporting a plurality of masses
182. With reference to FIG. 6, in some embodiments, a plurality of
energy storage devices 180 can be arranged along a slope or
hillside (or, in some embodiments, a cliff or other vertically or
steeply sloped surface) to provide a greater cumulative amount of
energy storage. Each of the plurality of energy storage devices 180
illustrated in the embodiment of FIG. 6 can be configured such that
masses 182 can be stored in and removed from the storage containers
183 and added to the cable or line 186. Each energy storage device
180 can be operated independently of the other energy storage
devices 180.
In some embodiments, the masses 182 can be removably or
non-removably supported by the cable 186. Further, the masses 182
can comprises carriers that can be each configured to move a
desired amount of mass from the lower to the higher elevation to,
for example, store energy, or from the higher elevation to the
lower elevation to, for example, create energy. The carriers can be
positioned about the entire length of the cable 186 and can be
controlled and configured to such that each carrier is
independently loadable with mass or such that each carrier can
independent support and discharge the mass. For example, for any of
the energy storage device embodiments disclosed herein, the
carriers could be a plurality of hooks, buckets, nets, or other
support members positioned along the length of the cable 186
wherein discrete masses or mass medium such as dirt, sand, rock,
gravel, crushed concrete, trash or refuse, liquid, hazardous waste
such as spent nuclear fuel, non-hazardous waste, or other
substances or materials could loaded into and removed from the
carriers at both the highest and lowest elevations, or at any
elevation along the path of the carriers.
Some embodiments of the energy storage device 180 or any other
energy storage device embodiment disclosed herein, the carriers can
be located on one or both sides of the cable and can be positioned
continuously or at uniform or non-uniform intervals along the
length of the cable. The energy storage device 180 or any other
energy storage device embodiment disclosed herein can be configured
such that the cable velocity is reversible, such that the cable
speed and acceleration are adjustable, and/or such that the masses
can be removed or adjusted in magnitude. Any energy storage device
embodiments disclosed herein can be configured such that the cable
direction is uni-directional or reversible.
In some embodiments, some of the energy storage device embodiments
can be operated such that the majority of the mass supported by a
given cable is generally supported on only one side of the cable or
cable loop at a given time. For example, some of the energy storage
device embodiments can be operated such that the 95% or more of the
removable mass supported by the cable (i.e., not considering the
non-removable components, such as the cable itself, the mass
carriers, or other components that may be non-removably supported
by the cable) is supported on one side of the cable at a given time
during operation. Some of the energy storage device embodiments can
be operated such that the 85% or more, or 75% or more, of the
removable mass supported by the cable is supported on one side of
the cable at a given time during operation.
FIG. 8A is an illustration of an embodiment of an energy storage
device 200, showing the energy storage device 200 in an energy
storage mode. FIG. 8B is an illustration of the embodiment of the
energy storage device 200 shown in FIG. 8A, showing the energy
storage device 200 in an energy generating mode. Some embodiments
of the energy storage device 200 can have any of the components,
features, or other details of any other energy storage device
embodiments disclosed herein, and can be oriented at any desired
angle or slope. In some embodiments, one or more masses 202 can be
supported by a cable system 206 supported along a sloping surface
or hillside by a first pulley 204a (also referred to as a first
bullwheel) and a second pulley 204b (also referred to as a second
bullwheel). In some embodiments, a plurality of masses 202 can be
supported along one side of the cable 206 (as illustrated) or along
both sides of the cable 206 (not illustrated).
The cable system 206 can be routed over a plurality of smaller
pulleys or guide wheels supported by one or more support towers or
support members (not illustrated) positioned along the slope. If
the energy storage device 200 is vertically oriented, support
towers may be omitted. The first bullwheel 204a can be positioned
at a lower elevation than the second bullwheel 204b. As with
previous embodiments, the second bullwheel 204b can be connected to
the motor/power generator 208 such that, when the operator of the
energy storage device 200 desires to store energy in the energy
storage device 200, the motor 208 rotates the second bullwheel 204b
in a first direction that causes the mass 202 to be pulled up the
slope to increase the potential energy of the energy storage device
200, as illustrated in FIG. 8A. FIG. 8A shows multiple masses 202
being transferred to a higher elevation. For some embodiments
disclosed herein, using multiple masses, as illustrated in FIG. 8A,
can permit more mass to be used, increasing the amount of energy
that can be stored in an energy storage device, while reducing the
structural requirements of the energy storage device.
Furthermore, the masses 202 can be adjustable, changeable, and/or
removable. Additionally, the spacing between the masses supported
by the cable 206, or any other cable disclosed herein, can be
changed. For example, a first container 210a can be positioned at
or near the bottom or lower portion of the energy storage device,
and a second container 210b can be positioned at or near the top or
upper portion of the energy storage device. The energy storage
device 200 can be configured such that the mass contained or
supported along the cable 206 can be partially or fully transferred
from the first storage container 210a onto the cable 206 (or into a
bucket or container supported by the cable 206), pulled up to the
higher elevation, and transferred into the second storage container
210b during the power storage mode (illustrated in FIG. 8A).
In any of the energy storage device embodiments disclosed herein,
mass can be added to or removed from the system or the cable at any
position along the length of the cable. Similarly, storage
containers can be positioned at any position along the length of
the cable. For example, mass can be loaded to or unloaded from the
cable at the midpoint between the upper and lower elevations.
In contrast, when the operator of the energy storage device 200
desires to produce energy to the grid, power to the motor 208 can
be ceased and mass can be transferred from the upper storage
container 210b onto the cable system 206 whereby gravity can cause
the mass to descend down the slope or vertical descent toward the
lower elevation, thereby generating power in the motor/generator
208. When the masses reach the lower, first container, the mass can
be transferred into the first storage container 210a. In some
embodiments, the masses 202 can be removably supported by the cable
system 206, wherein the masses are transferred between the storage
containers and the cable system. In other embodiments, the cable
206 can support buckets or containers along the length of all or a
portion of the cable system, wherein the buckets or containers can
each support transferrable mass material, such as dirt, sand,
gravel, rocks, water, or any other suitable material.
In any energy storage device embodiments disclosed herein, as
mentioned, the masses can be transferred onto or off of the cable
or onto or off of the moving portion of the system at an upper and
a lower elevation, or any elevation therebetween. For example, any
energy storage device embodiment disclosed herein could have a mid
elevation having a storage container and being configured to
transfer mass to and from the cable or carriers supported thereby
and/or to and from the other moving components of the energy
storage device. Similarly, any energy storage device embodiments
disclosed herein can have one or more motors/power generators
positioned at any desired points along the length of the cable. For
example, an energy storage device embodiment can have one or more
motor/generators at an upper elevation, a lower elevation, a mid or
halfway elevation, and/or at any other positions along the length
of the cable. One or more pulleys, guides, and other components
interacting with the cable system can also be linked to generators
and/or motors.
The energy storage device 200 can be configured to transfer mass
from the buckets or moveable containers supported by the cable
system 206 to the storage containers 210a, 210b or vice versa, by
tipping, spilling, opening, dumping, or otherwise transferring some
or all of the contents of the moveable containers into the storage
containers 210a, 210b, or otherwise, releasing material through
discharge devices (which can be valves, releasable doors, or
otherwise) in the moveable containers into the storage containers
210a, 210b, or through any suitable means. The discharge devices,
which can be valves such as those on a hopper or other medium
container, can be controllably adjusted by a control system to
control the amount or flow rate of mass medium flowing through the
valve or releasable doors. Similarly, the energy storage device 200
can be configured to transfer the mass from the storage containers
210a, 210b to the moveable containers or containers supported by
the cable system 206 by pouring material from the storage
containers 210a, 210b into the moveable containers, by releasing
material through valves or releasable doors in the storage
containers 210a, 210b into the moveable containers, by scooping and
transferring the material from the storage containers into the
moveable containers, or through any other suitable means.
Thus, the carriers or buckets may be loaded with the material via
the lower container 210a, and then the buckets may be emptied at
the upper container 210b (and vice versa). After a bucket is
emptied, it may be carried via the cable 206 back to the other
container to be loaded with additional material, and the process
repeats as often as desired. Thus, the upper or lower containers
may contain orders of magnitude more material than can be held by
the buckets affixed by the cable 206, or that the cable 206 could
support. Yet, using the illustrated approach, all of the material
may be moved from one container to the other container. This
technique greatly reduces the expense and size of the cable 206,
associated support towers, and other associated weight bearing
components, and provides greater adjustability to the amount of
mass supported by the cable and, hence, the amount of speed and
kinetic energy in a line.
FIG. 9 is a side view of an embodiment of an energy storage device
300, and FIG. 10 is an enlarged view of a portion of the embodiment
of the energy storage device 300 illustrated in FIG. 9. Any of the
features, components, or other details regarding the energy storage
device 300 can be the same as or similar to any of the features,
components, or other details of any other energy storage device
disclosed herein. Similarly, any of the features, components, or
other details of any energy storage device embodiments disclosed
herein can be the same as or similar to any of the features,
components, or other details of the energy storage device 300
embodiments disclosed herein.
As will be described in greater detail, in some embodiments, the
energy storage device 300 can be configured such that mass can be
added and removed from the active components of the system (e.g.,
to and from the cable system, carriers, and/or other components
that exert a force on the motor/power generator or are powered by
the motor/power generator), depending on whether the system is
producing or storing energy and/or whether the system is being used
for energy regulation. For example, mass can be added to and/or
removed from a cable 306 linked to a motor/power generator 308, and
can be stored at least one of two different elevational positions
of the energy storage device 300, depending on whether energy is
being stored by the energy storage device (by transferring mass
from a lower to a higher elevation) or whether energy is being
generated by the energy storage device (by transferring mass from a
higher to a lower elevation).
In some embodiments, with reference to FIGS. 9 and 10, one or more
masses 302 can be supported by a cable system 306 supported along a
sloping surface or hillside by a first pulley 304a (also referred
to as a first bullwheel) and a second pulley 304b (also referred to
as a second bullwheel). In some embodiments, a plurality of masses
302 can be supported along one side or both sides of the cable 306.
In the embodiment illustrated in FIG. 9, the masses 302 can be
supported along both sides of the cable 306, but are illustrated
along a portion of the cable for clarity of the drawing. The
plurality of masses 302 can each comprise a fillable container 303
supported by the cable. Again, only some of the carriers 303
supported by the cable 306 of the energy storage device 300 are
shown in FIG. 9 for clarity. In some embodiments, the masses 302,
some or all of which can comprise mass or material carriers 303,
can be continuously supported along the entire length of the cable
306.
The carriers 303 can be made from any suitable material, including
steel, aluminum, other metal, plastic, composite materials,
fiberglass, cloth, rubber, and/or any combination of such
materials. The carriers 303 can be supported along the cable 306
such that at least a top perimeter of the carriers 303 each
approximately abut one another along the length of the cable 306,
at least when the adjacent carriers 303 are at the same elevational
position. Additionally, the carriers 303 can be supported by the
cable system 306 so that the connection with the cable system
projects from a side of the cable system 306 and/or is otherwise
configured such that the bullwheel, guides, rollers, and other
components of the cable system do not interfere with the movement
of the carriers 303. Further, as shown, the carriers 303 can have a
round profile beneath the upper edge to permit the carriers 303 to
rotate to discharge mass or material 307 without interfering with
adjacent carriers 303. Additionally, the rounded or spherical
profile of the carriers 303 can reduce the interference between the
adjacent carriers 303 as the carriers 303 are traveling up or down
the inclined portion of the cable system. Additionally, in some
embodiments, the carriers 303 can be compartmentalized to prevent
or inhibit gravel from shifting during operation up or down the
slope.
As used in this context, the term approximately abutting means that
little or no gap is present between each of the carriers 303 when
the containers are being filled with mass medium (such as the mass
medium 307 illustrated in FIGS. 9-11) so that little or no of the
mass medium being added to the containers passes between the
carriers 303 when such carriers 303 are being filled to improve the
efficiency of mass transfer. As mentioned above, in any of the
embodiments disclosed herein, the mass or mass medium used for the
energy storage device can be a solid material such as rock, gravel,
dirt, mine tailings, sand, ice, snow, water, pulverized asphalt or
concrete, or any other man-made or natural occurring material or
substance. The transfer of the mass medium to and from the carriers
will be described in greater detail below.
Alternatively, the carriers 303 can be supported by the cable 306
at any desired position and in any desired number or spacing along
the length of the cable 306. For example, without limitation, the
carriers 303 can be spaced such that one or more inches (2.54 or
more centimeters) of space is present between two or more or each
of the carriers 303, such that one or more feet (0.305 meters or
more) of space is present between two or more of the carriers 303,
or at even larger intervals.
In some embodiments, the carriers 303 can comprise a continuous
flexible netting or sling suspended from the main cable 306 or from
a plurality of cables (not illustrated). In some embodiments, the
sling can be inverted to discharge mass supported thereby, or the
masses can be discharged therefrom using rollers, guides, or
otherwise to manipulate the sling material. For example, a central
array of wheels could be used to discharge the mass from the
sling.
Additionally, in some embodiments, the energy storage device 300 or
any other energy storage device disclosed herein can be configured
such that the carriers can be removably supported by the cable 306,
and/or such that the positioning of the carriers 303 on the cable
306 can be adjusted either before or during operation of the energy
storage device 300 (for example, when the cable 306 is stable or
when the cable 306 is moving). The energy storage device 300 or any
other energy storage device disclosed herein can be configured such
that the removal and/or positioning of the carriers 303 can be
adjusted and controlled by an operator of the energy storage device
300 or automatically by a control system of the device. For
example, the control system of the energy storage device 300 can
have pre-programmed algorithms to control the operation of the
device 300 depending on or to accommodate a variety of different
operating conditions or energy grid conditions.
As with other embodiments herein, the cable system 306 can be
routed over a plurality of smaller pulleys or guide wheels
supported by one or more support towers or support members (not
illustrated) positioned along the slope. If the energy storage
device 300 is vertically oriented, support towers may be omitted.
The first bullwheel 304a can be positioned at a lower elevation
than the second bullwheel 304b. The second bullwheel 304b can be
connected to the motor/power generator 308 such that, when the
operator of the energy storage device 300 desires to store energy
in the energy storage device 300, the motor 308 rotates the second
bullwheel 304b in a first direction that causes the masses 302 to
be pulled up the slope to increase the potential energy of the
energy storage device 300. For some embodiments disclosed herein,
using multiple masses can permit more mass to be used, increasing
the amount of energy that can be stored in an energy storage
device, while reducing the structural requirements of the energy
storage device.
Furthermore, as mentioned, the masses 302 can be adjustable,
changeable, or removable. For example, a first mass or pile 310a of
mass medium 307 can be positioned at or near the bottom or lower
portion of the energy storage device, and a second mass or pile
310b of mass medium 307 can be positioned at or near the top or
upper portion of the energy storage device 300. The energy storage
device 300 can be configured such that the mass contained or
supported along the cable 306 can be partially or fully transferred
from the first mass or pile 310a into the carriers 303 supported by
the cable 306, pulled up to the higher elevation, and transferred
into the second mass or pile 310b during the power storage mode or
operation of the energy storage device 300.
In contrast, when the operator of the energy storage device 300
desires to produce energy to the grid, power to the motor 308 can
be ceased and mass can be transferred from the upper mass or pile
310b onto the cable system 306 whereby gravity can cause the mass
to descend down the slope or vertical descent toward the lower
elevation and transferred to the first or lower mass or pile 310a,
thereby generating power in the motor/generator 308. Such power can
be transferred to the grid through a power electronics system or
module. The mass medium 307 can be transferred to the carriers 303
in any of a variety of means.
For example, the mass medium 307 can be passed through one or more
controllable discharge devices 320, which can be valves, releasable
doors, or otherwise such as those on a hopper or other medium
container, can be supported or positioned beneath the mass or pile
310a, 310b of medium 307. The one or more discharge devices 320 for
each mass or pile 310a, 310b can be positioned such that the
material flowing through the valve is not blocked by the cable. The
discharge devices 320 can be controlled by one or more control
systems 324 of the device 300 (not illustrated). When the discharge
devices 320 are opened, the mass medium 307 can be dumped, poured,
or otherwise transferred into the carriers 303. In this
arrangement, the carriers 303 can be routed under the mass or pile
310b through a tunnel or otherwise by the cable system 306. In some
embodiments, one or more movable valve mechanisms can be positioned
under each pile.
Alternatively, one or more hopper systems can be used in addition
to or in place of the valve systems and piles 310 to transfer the
mass medium from the mass or piles 310a, 310b to the carriers. An
embodiment of a hopper system 325 is illustrated in FIG. 11B. The
hopper system 325 can be used in place of one or more of the piles
310 and valve systems discussed with reference to the other
embodiments disclosed herein. The hopper 325 can be actuated to
discharge the medium 307 in the carriers 303 as the carriers 303
pass beneath the output of the hopper 325. The controllable
discharge device(s) 320, the hopper systems, and/or any other
suitable mass transfer mechanism can be configured to provide an
intermittent or pulsed flow of mass therethrough at any desired
flow rate, or can be configured to provide a continuous flow of
mass therethrough at any desired flow rate.
Additionally, in some embodiments, one or more sensors can be
integrated into any examples of the energy storage devices
disclosed herein. For example, sensors can be used to determine the
position and/or volume of the mass medium at the various locations
in the energy storage devices (including the site piles), the
volume of mass medium in the carriers, the position of the carriers
for locating the tipping mechanism, the position of the carriers
for dispensing the mass medium into the carriers, the position of
the one or more dispensing mechanisms (for example, if such
dispensing mechanisms are movable), or for any other purpose. The
sensors can be configured to provide feedback positional,
volumetric, or other gathered data back to the energy storage
device operator, the control system, or otherwise.
In this operational scenario wherein power is desired to be
produced to the grid, when the masses 302 along one side of the
cable system 306 reach the lower, first mass or pile 310a, the mass
medium 307 in each carrier 303 can be transferred onto the first
mass or pile 310a. In some embodiments, the carriers 303 on one
side of the cable system 306 can be routed over the first, lower
mass or pile 310a so that the mass medium 307 in each of the
carriers 303 can be dumped, poured, or otherwise transferred onto
the top of the mass or pile 310a. In some embodiments, the carriers
303 can be configured to be tipped by a tipping mechanism at
desired positions relative to the mass or pile 310. For example,
without limitation, a controllable tipping mechanism controlled by
the control system 324 may be movably positioned at any desired
position relative to the first, lower mass or pile 310a. The
tipping mechanism may be supported by a separate cable system that
allows the tipping mechanism to travel therealong.
Therefore, the energy storage device 300 can be configured to
transfer mass from the carriers 303 supported by the cable system
306 to the mass or piles 310a, 310b or vice versa, by tipping or
dumping the contents of the moveable containers in any direction
onto the mass or piles 310a, 310b, releasing material through
valves or releasable doors in the carriers 303, or through any
suitable means. Similarly, the energy storage device 300 can be
configured to transfer the mass from the mass or piles 310a, 310b
to the carriers by pouring material from the mass or piles 310a,
310b into the moveable carriers by releasing material through
valves or releasable doors beneath the mass or piles 310a, 310b
into the moveable carriers, by scooping and transferring the
material from the mass or piles 310a, 310b into the carriers 303,
or through any other suitable means.
FIG. 12A is a perspective view of the embodiment of the energy
storage device 300 illustrated in FIG. 9, taken from an upper view,
showing the path of movement of a first loop of the cable system
306. FIG. 12B is a perspective view of the embodiment of the energy
storage device 300 illustrated in FIG. 9, taken from an upper view,
showing the path of movement of a second loop 306b of the cable
system 306. FIG. 13 is a perspective view of the embodiment of the
energy storage device 300 illustrated in FIGS. 12A and 12B, taken
from an upper view. FIG. 14 is a perspective view of the embodiment
of the energy storage device 300 illustrated in FIG. 9, taken from
a lower view, showing the path of movement of a first and second
loops of the cable system 306. With reference to FIGS. 9-13, the
upper bullwheel system 304b can be configured and supported in a
manner and using structural supports and framework necessary for
the cumulative mass or load to be carried by the cable system 306.
For example, in some embodiments, the bullwheel systems 304a, 304b
or any other components of the energy storage device 300, including
the pulleys, towers, cable system, or other related components, can
be made and installed in a manner that is similar to that of a ski
lift, gondola, tram system, or other moveable cable suspension
system. Such details are well known to those of ordinary skill in
the art. The first or lower bullwheel 304a can be similarly
configured as compared to the second bullwheel 304b.
As illustrated in FIG. 12A, the second or upper bullwheel system
304b can have a first wheel 330, a second wheel 332, and/or other
wheels that can be connected to other motor generators along the
line. For example, a third set of bull wheels can be positioned at
the mid point of the elevation difference between the upper and
lower elevations. In some embodiments, though not required, the
second wheel 332 can be offset or eccentric as compared to the
first wheel 330, which can minimize or prevent interference between
carriers 303 on the first cable loop system 306a and the second
cable loop system 306b. The first wheel 330 and the second wheel
332 can be driven by the same shaft or by separate shafts, as
illustrated. Additionally, the first wheel 330 and the second wheel
332 can be driven by different motor generators. Further, some
energy storage device embodiments can have a one or more motor
generators positioned at the top elevation for each of the wheels
or for both of the wheels, one or more motor generator positioned
at the lower elevation for each of the wheels or for both of the
wheels, and/or one or more motor generator positioned along the
length of the cable at a third elevation for generating energy or
providing energy for storage.
In some embodiments, the adjacent wheels (such as, without
limitation, wheels 330, 332) can be supported on separate axles
that are independently controllable such that the wheels (e.g.,
wheels 330, 332) counter-rotate relative to one another. Thus, in
some embodiments, the wheels can be independently controlled to
rotate in opposite directions or in the same direction relative to
one another. For example, with reference to FIG. 12A, the first
wheel 330 can be supported by a first shaft 331 and can be
configured to rotate in a first direction A1, while the second
wheel 332 can be supported by a second shaft 333 and can be rotated
in a second direction A2 that is opposite the first direction.
Some embodiments of the energy storage device can be configured
such that the carriers 303 that are moved to the second, higher
elevation always travel under the mass piles or portions 336, 338
before traveling over the mass piles or portions 336, 338. This
control measure can ensure that the carriers 303 are not
intermittently emptied or filled and can ensure that the carriers
on one side of each cable are consistently loaded with mass. In
this arrangement, switching between energy storage and energy
production can be achieved by reversing the direction of rotation
of the wheels and the cable system. Any of the structural or
operational configurations described herein with respect to one
portion of an energy storage device embodiment can be applied to
other portions of the energy storage device embodiments. For
example, in some embodiments, the configuration and/or operation of
the portion of the energy storage device at the lower elevation can
be the same as the configuration and/or operation of the portion of
the energy storage device at the higher elevation.
In some embodiments, a system of pulleys and guides can be used to
minimize or prevent interference between carriers 303 on the first
cable loop system 306a and the second cable loop system 306b. In
this arrangement, the first and second wheels 330, 332 can be
approximately concentrically aligned.
With reference to FIG. 12A, with reference to the direction arrows
listed therein, if the buckets or carriers 303 were operationally
discharging mass on mass pile or portion 338, the system would be
considered to be in a charging or energy storage state. However, if
the buckets or carriers 303, moving in the same direction as
illustrated in FIG. 12A were receiving mass from mass pile 336, the
system would be considered to be in a discharging or energy
generating state.
Additionally, in some embodiments, the first and second wheels 330,
332 can have a different size to minimize or prevent interference
between carriers 303 on the first cable loop system 306a and the
second cable loop system 306b. For example, the first or lower
bullwheel system 310a can have a first wheel 330 that has a first
diameter and a second wheel 332 that has a second diameter, the
diameter of the first wheel 330 being bigger than a diameter of the
second wheel 332. Similarly, the second or upper bullwheel system
310b can have a first wheel 330 that has a first diameter and a
second wheel 332 that has a second diameter, a diameter of the
first wheel 330 of the second bullwheel system 310b being bigger
than a diameter of the second wheel 332 thereof. A first cable loop
306a can be connected to the first wheel 330 of the first bullwheel
system 310a and the second wheel 332 of the second bullwheel system
310b. A second cable loop 306b can be connected to the second wheel
332 of the first bullwheel system 310a and the first wheel 330 of
the second bullwheel system 310b. Each of the first and second
bullwheel systems 310a, 310b can have motor/power generator 308 so
that the torque and power produced or generated by each of the
first and second bullwheel systems 310a, 310b can be moderated and
independently controlled.
FIG. 12A shows the path of movement of carriers 303 moving along a
first, changeable direction of the first cable system 306a. Only
some of the carriers 303 that can be supported by the first cable
system 306a are shown, for clarity. As illustrated by the motion
arrows in FIG. 12A, carriers 303 supported by the first cable
system 306a can travel up the incline, under the first pile or mass
336, around the second wheel 332 and be directed to move over the
second pile or mass 338 by rollers, guides, or otherwise. In this
arrangement, the carriers 303 can be filled by the first pile 336
and/or the carriers 303 can dump or otherwise transfer the mass 307
to the top of the second pile 338. In a typical operational
arrangement, the carriers 307 moving along one cable loop would
only either receive or discharge mass at one elevational position,
since both receiving and discharging mass at the upper elevational
position, for example, could result in a zero net gain or loss of
mass at such elevation and would not result in the generation or
storage of energy.
FIG. 12B is a perspective view of the embodiment of the energy
storage device 300 illustrated in FIG. 9, taken from an upper view,
showing the path of movement of a second loop 306b of the cable
system 306. For illustration purposes, the upper bullwheel system
304b is rotating in the same direction as in FIG. 12A. Again, only
some of the carriers 303 that can be supported by the second cable
system 306b are shown, for clarity. As illustrated by the motion
arrows in FIG. 12B, carriers 303 supported by the second cable
system 306b can travel up the incline, over the first pile or mass
336, around the first wheel 330 and be directed to move under the
second pile or mass 338 by rollers, guides, or otherwise. In this
arrangement, the carriers 303 can discharge the mass 307 onto the
first pile 336 and/or the carriers 303 can be filled with the mass
307 by the second pile 338.
FIG. 15 is a perspective view of a plurality of energy storage
devices 300 arranged about a hillside. With reference to FIGS.
9-15, the mass medium piles 336 and 338 can be positioned adjacent
to one another so as to be laterally supported by one another. In
other words, the first mass pile 336 can be supported laterally on
one side by the second mass pile 338. A dirt berm such as is
positioned adjacent to the first mass pile 336 near the upper
bullwheel 304b in FIG. 15, a wall, or other support structure can
be positioned along any portion or all of the perimeter or on the
outside of the outermost mass pile or any mass pile for support, or
the outermost mass pile can be allowed to spread laterally, as
shown in the lower portion of the energy storage device 300 in FIG.
15. Any number of mass piles and cable systems can be used in a
single energy storage device facility, depending on such factors as
the amount of energy desired to be stored, the size of each mass
pile or mass system of each cable system, the structural support
requirements of each cable system, and the number of different
cable systems 306 that are desired to be built in the facility.
Further, additional cable systems 306 can be added to the system as
desired.
With reference to FIG. 13, with the upper bullwheel 304b rotating
in a first direction A3, the movement of the first cable system
306a will move in the direction indicated by arrows A3. Further,
with the lower bullwheel 304a rotating in a second direction A4
that is opposite direction A3, the movement of the second cable
system 306b will move in the direction indicated by arrows A4. With
reference to FIG. 14, which is a perspective view of the embodiment
of the energy storage device 300 illustrated in FIG. 9 taken from a
lower view, with the lower bullwheel 332 rotating in the direction
A3 and the upper bullwheel 330 rotating in the direction A4, the
movement of the first and second cable systems 306a, 306b will
travel in the directions indicated by the arrows shown on FIG.
13.
As mentioned, in some embodiments, the second wheel 332 can be
offset or eccentrically supported as compared to the first wheel
330, which can minimize or prevent carriers 303 supported on the
first cable loop system 306a from interfering with carriers 303
supported on the second cable loop system 306b. For example,
pulleys 311a, 311b can be used to guide and/or support the first
cable 306a. Pulleys 311c, 311d can be used to guide and/or support
the second cable 306b. In some embodiments, as in the illustrated
embodiment, the second bullwheel 332 can be positioned so as to be
offset in an x-direction as compared to the first bullwheel 330.
Similarly, both of the pulleys 311c, 311d supporting second cable
306b can be positioned so as to be offset in an x-direction as
compared to the pulleys 311a, 311b supporting cable 306a. In some
embodiments, if the offset is at least slightly greater than a
width of the carriers 303, then there will not be interference
between the carriers 303 on the first and second cables 306a, 306b.
A similar arrangement can be used for the lower elevation.
FIG. 16 is a perspective view of a tipping trigger or member 340
that can be used to activate the discharge of the medium 307
carried by the carriers 303. In some embodiments, the tipping
member 340 can interact with a lever, pin, or other similar object
342 positioned on an outside surface of one or more of the carriers
303. For example, the tipping member 340 can have an angled surface
346 that can engage the lever 342 of one or more of the carriers
303, causing the carrier 303 to rotate about an axis (concentric to
an axle, for example) as the carrier 303 is moved relative to the
tipping member 340, as in the direction represented by arrow A2.
The tipping trigger or member 340 can be movable relative to the
carriers 303. For example, in some embodiments, the tipping member
340 can be supported by one or more cables 350 such that either the
cable or cables are moveable or the tipping member 340 is movable
along the cable 350.
In some embodiments, the dumping mechanism can have a spreader
mechanism to put more gravel in a shorter pile. The spreader
mechanism can be configured to use the potential energy of the
gravel pile. The spreader mechanism can be similar to or comprise a
fertilizer spreader, a fixed conical ramp, and/or a rotating
conical spreader ramp.
The carriers 303 can be biased and configured such that, as the
carriers 303 move away from the tipping member 340 after the medium
307 carried by the carriers 303 has been dumped, the carriers 303
rotate back to a first or carrying position or orientation wherein
they can be loaded with medium. In some embodiments, the carriers
303 can be spring loaded, eccentrically supported, or otherwise
configured to resist rotation so that the carriers 303 remain in
the first or carrying position when being loaded with medium 307,
to prevent inadvertent tipping and discharge of medium 307.
Note that the cable 306 need not move for the tipping function to
be activated. In some embodiments, the tipping member 340 can be
moved relative to stationary carriers 303 to cause the carriers 303
to tip and discharge the mass medium 307 if desired. However, the
tipping member 340 can be held in a fixed position or moveable
above the piles 310 so that the carriers 303 can be discharged at
any desired position along the piles 310 to maintain a consistent
level of medium across the piles 310.
Any of the energy storage device embodiments disclosed herein can
be configured to support a preformed weight mass, such as the
masses 182' illustrated in FIG. 17. For example, without
limitation, each energy storage device 180 embodiment illustrated
in FIG. 6 can be configured such that one or more preformed masses
can be added or removed from the cable 186. In some embodiments,
the masses 182' can be round and rollable to facilitate handling
(e.g., automatic loading and unloading) and storage of the masses
182'. The masses 182' can be configured to roll on racks or rails,
such as may be formed on the inside of a standard shipping
container. The container 183 can be configured such that the masses
182' can be added to the top of the container 183 as energy is
stored (for example, at the top of the elevation or slope) or as
energy is generated (for example, at the bottom of the elevation or
slope). The container can be configured such that the masses 182'
roll down the ramping inside the container to a discharge opening
183a to be removed and added to the cable system 186.
The elevation change or slope for the energy storage can be
provided by situating the storage facility wherever there is
sufficient elevation change. Because any of the energy storage
devices embodiments disclosed herein can be scaled or sized
according to the target location or site, the number of suitable
and conveniently located sites appropriate for energy storage
devices is maximized. For example, natural hillsides, slopes,
cliffs, mountains, abandoned or even operational open-pit mines and
rock quarries can be suitable locations for some embodiments of the
energy storage devices disclosed herein.
The power that can be generated by some embodiments disclosed
herein can be calculated approximately with reference to the
equation P=F*V, where P is power, F is force, and V is velocity. In
most power generation systems, such as an internal combustion
engine, both F and V are varied. In some energy storage device
embodiments disclosed herein, such as embodiments where the masses
are not removable or adjustable, F (force) can be held constant and
V can be varied. However, some energy storage device embodiments
disclosed herein allow for adding and removing mass from the system
or by varying the distance between masses, thereby resulting in
varying F.
When power is being generated at a specific level and the signal is
received from the grid to generate a different amount of power, the
speed of the lift can be changed in substantially real-time to
change to the new power production setting, due to the correlation
between power and velocity (optionally without halting the supply
or storage of energy). For example, if the lift were generating
power by lowering the weights, and then more power was needed to be
generated, the speed of the line would need to be increased. In
order to increase the speed of the line, the line needs to
accelerate. The resistance to motion of the cable or line is caused
by the motor/power generator. In other words, what had been holding
the cable or line at steady state or resisting the motion of the
cable was the drag imposed on the cable by the motor/generator that
was converting the motion into usable energy and electricity. In
order to accelerate the line, without changing the mass on the
line, the power being produced must be temporarily lowered or
ceased, thereby reducing the drag on the line and allowing gravity
to accelerate the masses up to the new desired speed, and then
power must be drawn again or increased. In sum, in some
embodiments, if the desired power output is to be increased, the
power output must be temporarily decreased or ceased until the new
line speed is reached, and then the increased power can be drawn,
reverting the line to a new desired velocity or a steady state
velocity.
The opposite phenomena can occur when the power being produced is
desired to be decreased. In this case, the speed of the line can be
reduced to a new desired set point. To reduce the speed of the
line, the power drawn from the line can be temporarily increased,
in order to slow the line down. Alternately, a brake can be applied
to slow the line down, although this reduces round-trip efficiency.
In this case, if a decreased power is desired, the level of power
generation can be temporarily increased until the new, slower line
speed is reached, and then the decreased power can be drawn.
Additionally, the velocity of the line and power generated can be
adjusted by adjusting the mass supported by the line. For example,
if it is desired to increase the power generated by the line or the
velocity of the line, the amount of mass added to the line can be
increased. Alternatively, if it is desired to decrease the power
generated by the line or the velocity of the line, the amount of
mass added to the line can be decreased.
The system can be tailored to meet different energy storage
markets--from the rapid fluctuations required to balance transient
instabilities in the grid by supplying frequency regulation
ancillary services, to bulk storage applications requiring the
storage of large amounts of electricity. This is accomplished by
changing the amount of weight stored in the storage containers, and
the amount of weight stored at any one time upon the haul rope,
depending on the specific installation's needs.
A system which consists of a set of masses, connected to a
generator via a linkage, descending from one elevation to a lower
elevation, moving at a constant velocity, will generate power
according to the following formula:
.times..times..times..times..times..times..times..times..times..times..ti-
mes..theta..function..times..times..theta..times..times..times..times..tim-
es..times..times..times..times..times. ##EQU00001##
Holding mass constant, knowing that g and .theta. are fixed, one
way to change the power is to adjust v. If more power is desired
from the system, v needs to increase. If less power is desired, v
needs to decrease.
The means used to control the speed of the descending masses,
wherein the mass supported by the system is held constant, is
through control of the power drawn from the system. In order to
increase the speed of the masses, with mass being constant, the
power drawn from the system can be reduced for a period of time,
allowing the masses to accelerate to the desired higher speed.
Likewise, in order to decrease the speed of the masses, the power
drawn from the system can be increased for a period of time,
decelerating the masses. This presents a non-intuitive design. If
greater power is required, the power draw from the system can be
temporarily decreased. If less power is required, the power draw
from the system can be temporarily increased. However, in some
embodiments, where the mass supported by the system can be
adjusted, adjusting the power drawn from the system or stored by
the system can be achieved by changing the mass supported by the
system.
In any of the energy storage devices ("ESD") embodiments disclosed
herein, for example ESD 300, the magnitude of energy storage and
energy generation can be adjusted in a number of different ways
during the operation of the ESD. For example, in some arrangements,
the magnitude of the energy stored and the energy generated can be
adjusted by increasing or reducing the aggregate amount of mass
that is being moved by the system from one elevation to a second,
different elevation. If, for example, the carriers along one side
of the cable system going from a lower to a higher elevation are
consistently filled to 80% of their individual capacities,
increasing the mass of each carrier to 100% can increase the
magnitude or rate of energy storage. Further, increasing the speed
of the cable system can also increase the magnitude or rate of
energy storage. If the masses supported by the cable system are
removable, increasing the mass supported along one side of the
cable system by decreasing the spacing between masses or increasing
the magnitude of at least one of the masses supported along one
side of the cable system can increase the magnitude or rate of
energy storage or energy reduction. Increasing the cable velocity
in this arrangement can also increase the magnitude or rate of
energy storage or energy reduction. Increasing velocity during
energy generation without adjusting the amount of mass supported by
the cable system, as discussed in greater detail elsewhere herein,
can be done by momentarily reducing the drag force on the cable
system by the motor generator to allow the cable to accelerate. Any
combination of the foregoing operational methods can also be used
to adjust the rate of energy storage or energy production.
Further, some embodiments can be switched from an energy production
mode to an energy storage mode (or vice versa) by changing the
direction of movement of the cable. Additionally, some embodiments
can be switched from an energy production mode to an energy storage
mode (or vice versa) by permitting the masses to be run around the
bullwheels and to move in the opposite direction on a particular
cable system.
Shown in FIGS. 18-20 are three responses to actual frequency
regulation data from the grid operator PJM (serving Pennsylvania,
New Jersey, Maryland and others). By adjusting the maximum
acceleration of the masses, the reaction time to adjust the
velocity can be reduced. The maximum acceleration can be adjusted
by adjusting the power that is drawn from the motor/generator. If
the motor/generator were completely removed from the line, then in
the example embodiments the maximum acceleration would be based on
the force of gravity (9.8 meters/second^2), or
gravity.times.sin(A), where A is the angle of the hill. The motor
controller can control the torque of the motor on the line, so this
can be adjusted in real time. However, in doing so, the peak power
increase or decrease, preceding the adjustment is either increased
or decreased. Through this "reversal-method" of control, by
temporarily increasing power when an overall decrease is required,
or temporarily decreasing power when an overall increase is
required, the system can be made to respond rapidly to large power
surges required to provide frequency regulation for the electric
grid. The responsiveness of the system to changes in power
requirements can also be affected by the time required to make
adjustments to the system, for example, the time required to
temporarily decrease the power output of the motor/generator or the
time required to adjust the mass on the system.
In some embodiments, when providing frequency regulation, the
control system can receive the requested power level from the grid
operator and determine the optimal adjustments for the device to
meet the requested power. One embodiment of this implementation can
use a software controller to implement the phenomenon described
above for controlling a single mass lift. The following steps can
be followed. First, receive requested power from the grid operator
(Preq). Second, calculate desired mass velocity (Vdes), in
accordance with the following equation, where M=mass on line,
g=gravitational constant, and .theta.=slope of line.
.times..times..times..times..theta. ##EQU00002##
Third, calculate the difference in velocity from the desired point,
where Vact=current speed of mass. Verr=|Vact-Vdes|
Fourth, a new velocity can be calculated given the acceleration
limit. For purposes of controlling the responsiveness of the
system, it can be useful to set a maximum acceleration. This can
prevent large load swings and power swings as the control system
adjusts the system performance, where V2=new velocity point,
Amax=maximum acceleration permitted, .DELTA.t=period of time
between calculation iterations. Amax*.DELTA.t is positive or
negative, such that V2 approaches or becomes equal to Vdes.
V2=Vact.+-.Amax.DELTA.t
Next, the new desired power setpoint can be calculated given new
V2:
.times..times..times..times..times..times..theta..DELTA..times..times..ti-
mes..times..DELTA..times..times. ##EQU00003##
Then, the power can be adjusted through the power electronics
module to the desired power (Pdes). Finally, return to step 1, at
time .DELTA.t later.
A second embodiment of the control system can be used when an array
of lifts is used. Each lift can include a cable and pulley, as
described in some embodiments disclosed herein. In this case, the
overall power produced is a sum of the producing cables of an array
of energy storage devices, each cable configured to raise or lower
one or more weights to either store energy or generate energy,
respectively. For example, if the full capacity of the system is
100 MW, and this is comprised of 10 lifts (or cable systems or
loops), each with a capacity of 10 MW, then as the control system
receives the requested power signal from the grid operator, the
control system can activate different lifts to produce power. In
this example, if 35 MW were required, this could be met with either
10 lifts operating at 3.5 MW, or with 3 lifts operating at 10 MW,
one lift operating at 5 MW and the remaining 6 lifts idle. In fact,
there may be situations when it might be advantageous to operate
with some lifts running the opposite direction, such as, in the
example provided, 6 lifts at 10 MW, one lift at 5 MW, 3 lifts
charging at 10 MW, and one lift idle. These are some of the
different control options available with a multi-lift array
embodiment.
FIG. 21 is a graphical representation of a simulation of actual
power output, desired power output, and height (or vertical
position) of the mass in the system. FIG. 21 illustrates a special
case that can occur in some embodiments when the weights change
direction, and the cable goes through a V=0 point. At this time,
the amount of power being produced is zero. These adjustment
periods can be long, and the system may not be complying with the
desired power production during these periods. This is demonstrated
by applying a desired signal of +100% and -100% of the desired
output to the system, which is an extreme, hypothetical worst case
scenario that does not necessarily represent actual real-world
conditions. This illustrates that rapid response time may be
beneficial. Typical frequency regulation requirements, although
changing every 2 seconds, do not exhibit this kind of
volatility.
Actual data was input into a model of an embodiment of an energy
storage device to observe the response. Data from Dec. 1, 2009 for
the PJM fast response frequency regulation signal was used, for the
hour between 12:00 am and 1:00 am. The response can be seen in FIG.
22. FIG. 22 shows that the time lag for a output adjustments, are
less than 0.01 s. Secondly, the quick spikes or drops in power
production do not exceed the maximum power production of the
generators. The spikes are very quick, because the maximum
acceleration was set to 9.8 meters/second^2. In any energy storage
device embodiments disclosed herein, the control system can be
configured to determine the maximum acceleration in real time
depending on the optimum balance between spike height and response
time. As mentioned, 9.81 meters/second^2 is the maximum
acceleration possible, assuming a vertical rope, no energy loss,
and a completely decoupled motor/power generator. While this is
suitable for adjustments needed to increase the speed of the line,
as the power can be dropped off the line for very short periods of
time, allowing small accelerations to be made, it may be
challenging to achieve this rapid control when the line speed needs
to be reduced and more power is drawn from the line.
To examine the effects of reduced maximum acceleration, the maximum
acceleration can be reduced to g/20, or 0.4905 meters/second^2, as
illustrated in FIG. 23. With reduced acceleration, the response
time can be lower, but, with reference to FIG. 23, is still 0.14 s.
The spikes, however, can be seen to be dramatically less, which
implies far easier control for the motor and accurate ability to
meet the frequency regulation requirements. As a point of interest,
a period of the data where a V=0 event is encountered is shown in
the chart of FIG. 24. Notice that since the step changes are minor,
even this can be handled with very little overshoot or delay
periods. As long as the step changes are not too severe, the energy
storage device embodiments disclosed should be able to respond
adequately rapidly.
While it may be difficult for some embodiments of the energy
storage devices disclosed herein to respond quickly to a 200%
change or swing in energy demand (e.g., from -100% to +100%), at
least some embodiments are configured to adequately respond well to
smaller changes in demand. To determine what the typical adjustment
swings will be, a histogram of changes for the data is shown in
FIG. 25. It can be seen that typical operation is far less abrupt
than the +/-100% analysis, and is typically only +/-2%, which can
be easily controlled with at least some of the energy storage
device embodiments disclosed herein.
There are a number of parameters which can be modified to meet the
system needs, but these examples herein show just a few ways that
the real-world requirements of the frequency regulation system can
be met with very little response time, and small adjustments to the
system.
Illustrated in FIG. 26 is a flow chart of a method of energy
management according to one example embodiment. At the beginning of
a charge cycle, the energy storage system 100 is in an "uncharged"
state in which a substantial portion (e.g., substantially all) of
the mass or weight resides at a lower elevation level (e.g., at the
bottom of an incline or cliff). At state 402, the process (e.g.,
executed by the controller of the storage system 100) determines an
initial rate at which to consume power from the grid, this value
being referred to herein as the initial consumption set point
(ICSP). The ICSP and charge duration may be large enough to
adequately charge the system before the start of the next phase
described below. In general, the ICSP is based on a variety of
factors including, but not limited to, some or all of the following
factors: the energy storage capacity of the storage system, the
maximum power capacity of the device, the price of energy (in the
various long and short-term energy markets), and the prices of
ancillary services (non-spinning reserve, spinning reserve,
frequency regulation, and others).
If the storage system is operating in a charge-only mode, at state
410 the system begins drawing power from the grid in accordance
with the ICSP. On the other hand, if the storage system 100 is
configured to perform frequency regulation (FR) while charging,
decision state 404 is answered in the affirmative and, at state 406
the storage system monitors the grid operator signal for
instructions to implement frequency regulation in accordance with
the terms of a contract (e.g., a pre-arranged contract) defining
the time, duration, and power (e.g., the maximum power) to be
regulated.
In practice, certain embodiments of the storage system 100
implement frequency regulation while charging by consuming power at
the rate referred to herein as the target consumption set point
(TCSP). In an example embodiment, the TCSP is set equal to (a) the
sum of the fixed charge rate and the FR consumption rate when
commanded from the grid to net increase power consumption
(typically, when there is excess power on the grid), and (b) the
initial charge rate less the FR production rate when commanded from
the grid to net decrease power consumption (typically, when there
is excess demand on the grid). The storage system 100 may continue
to draw power from the grid until the consumption phase ends and
decision state 412 is answered in the affirmative. Thereafter, the
storage system may enter a transition phase 414 in which it sits
idle until the start of the next phase.
After charging, the storage system 100 may proceed to a frequency
regulation-only phase, power production phase, or combination of
power production and FR. If, in the FR-only phase as shown in FIG.
1B, decision state 420 is answered in the affirmative and the
system 100 monitors a signal from the grid operator indicating that
the system should either consume power from or deliver power to the
grid. If instructed to consume power, decision state 422 is
answered in the affirmative, and at state 424 the storage system
100 consumes power corresponding to or in proportion to the TCSP.
The absolute rate of power consumption may be dependent on the
terms agreed to with the grid operator. If instructed to produce
power, decision state 426 is answered in the affirmative, and at
state 428 the storage system outputs power corresponding to or in
proportion to the TPSP. The storage system 100 periodically checks
and revises (e.g., every few seconds) the amount of power consumed
and/or produced until the end of the frequency regulation phase at
state 430 (although optionally the system may thereafter monitor
power consumption and/or generation). Thereafter, the storage
system 100 may wait in a transition phase 432 until the beginning
of the next phase, at state 434, which may be a power consumption
or power production phase.
In certain applications, the power production phase generally
begins in the afternoon when electricity prices are relatively high
and the storage system is fully or substantially "charged." At
state 440, the system 100 determines an initial rate at which to
produce power for the grid, this value being referred to herein as
the initial production set point (IPSP). The rate and duration of
power production may be large enough to adequately discharge the
system before the start of the next charge phase.
If the storage system 100 is operating in a production-only mode,
at state 448 the storage system 100 begins delivering power to the
grid in accordance with the IPSP. On the other hand, if the storage
system 100 is configured to perform frequency regulation while
discharging power, decision state 442 is answered in the
affirmative, and at state 444 the storage system 100 monitors the
grid operator signal for instructions to implement frequency
regulation (e.g., in accordance with the its agreement with the
grid operator).
An example embodiment of the storage system 100 implements
frequency regulation while producing by outputting power at the
rate referred to herein as the target production set point (TPSP).
In certain embodiments, the TPSP is substantially equal to (a) the
sum of the fixed output rate and the FR power production rate when
commanded from the grid to net increase power production
(typically, this may occur when there is excess demand on the
grid), and (b) the initial power output rate less the FR production
rate when commanded from the grid to net decrease power production
(typically, this may occur when there is excess power on the grid).
The storage system 100 continues to deliver power to the grid until
the production phase ends and decision state 450 is answered in the
affirmative. Thereafter, at state 452, the storage system 100 may
enter a transition phase in which it sits idle until the start of
the next phase.
The systems and methods disclosed herein can be implemented in
hardware, software, firmware, or a combination thereof. Software
can include computer readable instructions stored in memory (e.g.,
non-transitory, tangible memory, such as solid state memory (e.g.,
ROM, EEPROM, FLASH, RAM), optical memory (e.g., a CD, DVD, Bluray
disc, etc.), magnetic memory (e.g., a hard disc drive), etc.,
configured to implement the algorithms on a general purpose
computer, special purpose processors, or combinations thereof. For
example, one or more computing devices, such as a processor, may
execute program instructions stored in computer readable memory to
carry out processed disclosed herein. Hardware may include state
machines, one or more general purpose computers, and/or one or more
special purpose processors.
While certain embodiments may be illustrated or discussed as having
certain example components, additional, fewer, or different
components may be used. Further, with respect to the processes
discussed herein, various states may be performed in a different
order, not all states are required to be reached, and fewer,
additional, or different states may be utilized.
Conditional language, such as, among others, "can," "could,"
"might," or "may," unless specifically stated otherwise, or
otherwise understood with the context as used, is generally
intended to convey that certain embodiments include, while other
embodiments do not include, certain features, elements, and/or
steps. Thus, such conditional language is not generally intended to
imply that features, elements, and/or steps are in any way required
for one or more embodiments or that one or more embodiments
necessarily include logic for deciding, with or without user input
or prompting, whether these features elements, and/or steps are
included or are performed in any particular embodiment.
Any process descriptions, elements, or blocks in the flow diagrams
described herein, and/or depicted in the attached figures, should
be understood as potentially representing modules, segments, or
portions of code which include one or more executable instructions
for implementing specific logical functions or steps in the
process. Implementations are included within the scope of the
embodiments described herein which elements or functions which may
be deleted, depending on the functionality involved, as would be
understood by those skilled in the art.
While the above detailed description has shown, described, and
pointed out novel features as applied to various embodiments, it
will be understood that various omissions, substitutions, and
changes in the form and details of the device or process
illustrated can be made without departing from the spirit of the
disclosure. Additionally, the various features and processes
described above can be used independently of one another, or can be
combined in various ways. All possible combinations and
subcombinations are intended to fall within the scope of this
disclosure.
As will be recognized, certain embodiments described herein can be
embodied within a form that does not provide all of the features
and benefits set forth herein, as some features can be used or
practiced separately from others. The scope of the inventions is
indicated by the appended claims rather than by the foregoing
description. All changes which come within the meaning and range of
equivalency of the claims are to be embraced within their
scope.
* * * * *